WO2019033996A1 - Fireproof embedded lamp and fireproof lamp housing - Google Patents

Abstract

The present utility model discloses a fireproof embedded lamp and a fireproof lamp housing, wherein the fireproof embedded lamp comprises a lamp housing, a light source device, and a fireproof device. The light source device and the fireproof device are both disposed in an internal space of the lamp housing, and the fireproof device separates the internal space of the housing into a lower space and an upper space. The fireproof embedded lamp is further provided with at least one heat dissipation channel, and each of the heat dissipation channels communicates with the lower space and the upper space to allow heat generated by the light source device to radiate from the lower space to the upper space via each of the heat dissipation channels. After undergoing expansion the fireproof device seals each of the heat dissipation channels to prevent the lower space and the upper space from communicating via the heat dissipation channels.

Description

Embedded fire protection lamp and fireproof lamp housing Technical field

The utility model relates to a lamp, in particular to an embedded fireproof lamp and a fireproof lamp shell thereof.

Background technique

A recessed luminaire is a luminaire that can be embedded in the ceiling and used to provide a light source to the indoor environment. Generally, the recessed lamp includes a lamp housing, a base, and a light source lamp cup, wherein the base is disposed in an inner space of the lamp housing, and the base is adapted to be connected to one An external power source, the light source cup is disposed on the base and is held in an inner space of the lamp housing, and the light source cup is electrically connected to the base, wherein There is a gap between the base and the inner wall of the lamp envelope and between the light source cup and the inner wall of the lamp envelope. In addition, the top of the lamp housing is provided with heat dissipation channels, and the heat dissipation channels of the lamp housing and the lamp housing communicate with each other to allow air to flow in the inner space of the lamp housing, thereby ensuring the embedded lamp Thermal performance. However, the ceiling generally requires a wooden keel (wood beam or wood frame, etc.) to be suspended in the room, and the embedded luminaire is placed in the indoor environment of the room in such a manner as to be embedded in the mounting hole of the ceiling. The gap of the embedded luminaire and the heat dissipation channel may cause the upper space of the ceiling and the lower space to communicate while ensuring the heat dissipation capability of the embedded luminaire. If a fire occurs in the lower space of the ceiling, the fire generated by the fire will quickly spread to the upper space of the ceiling through the slit of the recessed luminaire and the heat dissipation passage, which easily causes the wood keel to burn, and once this When the situation arises, it will inevitably lead to the rapid spread of the fire. Therefore, how to improve the fireproof performance of the embedded luminaire while ensuring the heat dissipation capability of the embedded luminaire is a technical problem that the industry has long paid attention to and is committed to solve.

The technical solution illustrated in FIGS. 1A and 1B teaches a recessed light fixture with a fireproof expansion sheet, wherein the recessed light fixture includes a lamp housing 10P, a base 20P, a light source cup 30P, and a fireproof expansion. Sheet 40P. The lamp housing 10P has an inner space 11P, at least one lamp housing heat dissipation channel 12P, an exit channel 13P, and a wire channel 14P. Each of the lamp housing heat dissipation channel 12P and the wire channel 14P are respectively in the lamp housing. The top of the 10P communicates with the inner space 11P, and the exit passage 13P communicates with the inner space at the bottom of the lamp housing 10P, wherein the base 20P is disposed in the inner space 11P of the lamp housing 10P, And a wire source can extend to the inner space 11P of the lamp housing 10P via the wire passage 14P and be electrically connected to the base 20P, wherein the light source cup 30P is disposed in the a base 20P, and the light source cup 30P is electrically connected to the base 20P, and the light source cup 30P faces the exit passage 13P of the lamp housing 10P to allow the belt The light generated by the light cup 30P is radiated from the exit passage 13P to the use environment. The fireproof expansion sheet 40P has at least one expansion sheet heat dissipation passage 41P, wherein the fireproof expansion sheet 40P is disposed at the top of the lamp housing 10P, and the fireproof expansion sheet 40P is located outside the lamp housing 10P, wherein The expansion sheet heat dissipation passage 41P of the fireproof expansion sheet 40P and the lamp housing heat dissipation passage 12P of the lamp housing 10P correspond to each other and communicate with each other to ensure air can pass through the expansion sheet heat dissipation passage 41P and the lamp housing. The heat dissipation passage 12P and the inside of the lamp housing 10P flow to dissipate heat. When a fire occurs in the lower portion of the ceiling of the lamp housing 10P for fixing the recessed luminaire, if the fire spreads to the position of the recessed luminaire, the fireproof expansion sheet 40P expands rapidly when heated to The expansion sheet heat dissipation passage 41P of the fireproof expansion sheet 40P is quickly closed, and the lamp housing heat dissipation passage 12P of the lamp housing 10P is further closed, so that fire generated by the fire can be prevented or delayed. The internal space 11P of the 10P and the passages spread from the lower portion of the ceiling to the upper portion of the ceiling, thereby contributing to the fire.

Nonetheless, the recessed luminaires taught in Figures 1A and 1B still have significant drawbacks. First, the embedded luminaire dissipates heat only by disposing the lamp housing heat dissipation channel 12P on the top of the lamp housing 10P, which may cause the heat dissipation transmission channel of the embedded luminaire to be insufficiently smooth, which is disadvantageous for the The normal heat dissipation when the light source cup 30P is used is such that the service life of the embedded lamp is affected to some extent. Moreover, if the embedded luminaire shown in FIG. 1A and FIG. 1B wants to ensure normal heat dissipation, only a light source with a lower power can be selected, which results in a great limitation of the applicable range of the embedded luminaire. Secondly, the embedded luminaire dissipates heat only by providing the lamp housing heat dissipation passage 12P at the top of the lamp housing 10P, which causes the lamp housing heat dissipation passage 12P of the lamp housing 10P to be easily covered. The insulation wool at the top of the ceiling is clogged, which is not conducive to the normal heat dissipation of the embedded luminaire, and even causes the embedded luminaire to not dissipate heat through these channels, thereby affecting the service life of the embedded luminaire. That is to say, the recessed luminaire shown in FIGS. 1A and 1B is not suitable for an environment in which it is required to cover the ceiling with insulating cotton.

The technical solution illustrated in Figures 2A and 2B teaches another recessed light fixture with a fire resistant expansion sheet, which differs from the recessed light fixture illustrated in Figures 1A and 1B in Figures 2A and 2B. In the embedded lamp, the lamp housing heat dissipation passage 12P is disposed on a side wall of the lamp housing 10P, and the fireproof expansion sheet 40P is disposed at an upper portion of the lamp housing 10P and is held at the lamp The inside of the internal space 11P of the casing 10P, and the fireproof expansion sheet 40P is located at an upper portion of the lamp housing heat dissipation passage 12P, and the light source lamp cup 30P is located at a lower portion of the lamp housing heat dissipation passage 12P to send It is desirable that the heat generated by the light source cup 30P is rapidly radiated to the outside of the lamp housing 10P through the lamp housing heat dissipation passage 12P, and is less affected by the fireproof expansion sheet 40P as much as possible. In order to ensure the fireproof performance of the embedded luminaire, the exposed size of the lamp housing heat dissipation passage 12P of the lamp housing 10P should be smaller than or equal to the size of the fireproof expansion sheet 40P after being thermally expanded, such that the fireproof expansion After the sheet 40P is expanded, the lamp housing heat dissipation passage 12P of the lamp housing 10P can be closed to prevent and delay the fire generated flame from spreading from the lower space of the ceiling to the upper space through the lamp housing heat dissipation passage 12P. effect.

The problem with the embedded luminaire shown in FIG. 2A and FIG. 2B is that the size of the lamp housing heat dissipation passage 12P of the lamp housing 10P needs to be increased in order to improve the heat dissipation capability of the recessed luminaire. At this time, in order to ensure that the fireproof expansion sheet 40P can close the lamp housing heat dissipation passage 12P after being thermally expanded, the fireproof expansion sheet 40P needs to be made of a material having a high expansion coefficient, which may result in the embedded lamp. The cost has been greatly increased. If it is desired to reduce the manufacturing cost of the recessed luminaire by providing the fireproof expansion sheet 40P made of a material having a low expansion coefficient, the size of the lamp housing heat dissipation passage 12P needs to be reduced, which This will result in a significant reduction in the heat dissipation capability of the recessed luminaire. That is to say, if the heat dissipation capability of the embedded luminaire is to be improved, the cost of the embedded luminaire will be greatly increased, and if the manufacturing cost of the embedded luminaire is to be reduced, the embedding is inevitably caused. The heat dissipation capability of the luminaire is reduced. Further, when the size of the lamp housing heat dissipation passage 12P of the lamp housing 10P is increased, even if the fireproof expansion sheet 40P made of a material having a high expansion coefficient is selected, the fireproof expansion sheet 40P is subjected to It is also difficult to completely close all of the lamp housing heat dissipation passages 12P after thermal expansion, which affects the reliability of the recessed luminaire.

Utility model content

An object of the present invention is to provide an embedded fireproof light fixture and a fireproof light cover thereof, wherein the embedded fireproof light fixture can be embedded and held in a fixture attachment and prevent or delay the occurrence of a lower portion of the fixture attachment. The high temperature or flame generated by the fire spreads to the upper part of the fixture attachment.

An object of the present invention is to provide an embedded fireproof light fixture and a fireproof light cover thereof, wherein the embedded fireproof light fixture provides a direct and smooth heat transfer passage to facilitate the heat dissipation capability of the embedded fireproof light fixture, thereby Extend the service life of the embedded fire protection luminaire.

An object of the present invention is to provide an embedded fireproof light fixture and a fireproof light cover thereof, wherein the embedded fireproof light fixture provides a fireproof device capable of expanding through fire when subjected to high temperature or fire generated by a fire. The heat transfer passage is blocked in a manner to prevent or retard the high temperature generated by the fire or the flame propagates from the lower portion of the luminaire attachment to the upper portion via the heat transfer passage.

An object of the present invention is to provide an embedded fireproof lamp and a fireproof lamp cover thereof, wherein the fireproof device provides at least one fireproof expansion element, and the fireproof expansion element can be automatically used when encountering a high temperature or fire generated by a fire Expanding to block the heat transfer passage by, in such a manner, preventing or retarding the high temperature generated by the fire or the flame spreading from the lower portion of the luminaire attachment to the upper portion via the heat transfer passage.

An object of the present invention is to provide an embedded fireproof luminaire and a fireproof lamp housing thereof, wherein the fireproof expansion element automatically expands only when encountering a high temperature or a fire generated by a fire, and is used to block the heat transfer. aisle. In other words, when the heat generated by the embedded fireproof luminaire when the light is supplied is applied to the fireproof expansion element, the fireproof expansion element does not expand, and in this way, the embedded fireproof luminaire is ensured. Reliability and stability.

An object of the present invention is to provide an embedded fireproof luminaire and a fireproof lamp housing thereof, wherein the fireproof expansion element is allowed to be made of a material having a low expansion coefficient, and the fireproof expansion element encounters a high temperature generated by a fire. In the case of a fire, the heat transfer passage can be blocked by automatically generating expansion. In this way, the manufacturing cost of the embedded fireproof light fixture is reduced, thereby facilitating the large-scale application of the embedded light fixture. And popular.

An object of the present invention is to provide an embedded fireproof light fixture and a fireproof light cover thereof, wherein the embedded fireproof light fixture provides a casing made of a material resistant to high temperature, and the embedded fireproof light fixture passes through The manner in which the housing is embedded in the mounting hole of the lamp attachment is embedded in the fixture attachment, and the housing can be reliably held in the fire when a high temperature generated by a fire or a flame acts on the housing. The luminaire attachment is not detached from the luminaire attachment, in such a manner that the housing can ensure the high temperature generated by the fire or the flame does not come from the mounting hole of the luminaire attachment. The lower part of the fixture attachment spreads to the upper part.

It is an object of the present invention to provide an embedded fire protection luminaire and a fire protection lamp housing thereof, wherein the fire protection device provides a bracket for supporting the fireproof expansion element, wherein the bracket is for preventing the The fireproof expansion element is detached after expansion, thereby ensuring that the fireproof expansion element can effectively block the heat transfer passage after expansion, and in this way, the reliability and stability of the embedded fireproof luminaire are ensured.

An object of the present invention is to provide an embedded fireproof lamp and a fireproof lamp casing, wherein the bracket is made of a high temperature resistant material, so that even if a fire generates a high temperature or a flame acts on the bracket, The bracket can also hold the fireproof expansion member in an inner space of the housing by being held in an inner space of the housing, and ensure that the fireproof expansion member expands in an inner space of the housing .

An object of the present invention is to provide an embedded fireproof light fixture and a fireproof light shell thereof, wherein the fireproof expansion element is held in an inner space of the casing to divide it into an upper space and a lower space which are in communication with each other. At this time, the heat generated by the light source device of the fireproof lamp housing can be radiated from the lower space to the upper space to dissipate heat, and when the heat generated by the fire or the flame acts on the fireproof expansion element, the fire prevention The expansion member automatically expands to block the upper space from communicating with the lower space, in such a manner that heat generated by the fire or fire from the lower space to the upper space can be effectively prevented or retarded.

An object of the present invention is to provide an embedded fireproof light fixture and a fireproof light cover thereof, wherein a part of the light source device is held in the upper space, by which a part of the heat generated by the light source device can be The heat is directly radiated in the upper space to greatly improve the heat dissipation capability of the embedded fireproof luminaire.

An object of the present invention is to provide an embedded fireproof lamp and a fireproof lamp housing thereof, wherein the casing has at least one heat dissipation hole, and the heat dissipation hole communicates with the upper space and the side at a side of the casing In this way, even if the insulating cotton is covered on the upper part of the embedded fireproof lamp, the heat insulating cotton does not block the heat dissipation hole, thereby facilitating the heat dissipation of the embedded fireproof lamp. Ability to expand the scope of application of the embedded fire protection luminaire.

According to an aspect of the present invention, the present invention provides an embedded fireproof light fixture, comprising:

a lamp housing device, wherein the lamp housing device comprises a housing having an inner space and a low end opening communicating with the inner space;

a light source device, wherein the light source device is disposed in the inner space of the housing, and light generated by the light source device is radiated from the inner space to the chamber via the low end opening of the housing The exterior of the embedded fire luminaire;

a fire prevention device, wherein the fire prevention device is disposed in the inner space of the casing, and the fire prevention device separates the inner space to form a lower space and an upper space; wherein the embedded fireproof lamp further Having at least one heat dissipation channel, each of the heat dissipation channels respectively communicating the lower space and the upper space to allow heat generated by the light source device to radiate from the lower space to the upper portion via each of the heat dissipation channels a space, wherein the fire prevention device encloses each of the heat dissipation passages after expansion to prevent the lower space and the upper space from being communicated by each of the heat dissipation passages.

According to an embodiment of the present invention, the fire prevention device has a perforation that communicates with the lower space and the upper space, wherein the light source device passes through and is retained in the perforation of the fire protection device .

According to an embodiment of the invention, the fire protection device comprises at least one fireproof expansion element having an expansion element perforation, and the expansion element is perforated to form the perforation of the fire protection device, wherein A fireproof expansion element is retained in the interior space of the housing to separate the interior space to form the lower space and the upper space, wherein the expansion element encloses each of the heat dissipation channels after expansion.

According to an embodiment of the present invention, the fire prevention device includes at least one fireproof expansion element and a bracket, the fireproof expansion element has a perforation of the expansion element, the bracket has a bracket perforation, wherein the fireproof expansion An element is supported by the bracket, and the expansion element perforation and the bracket perforation correspond to each other to form the perforation of the fire protection device, wherein the bracket and the fireproof expansion element are located in the housing The inner space forms the lower space and the upper space to partition the inner space, wherein the expansion element encloses each of the heat dissipation channels after expansion.

According to an embodiment of the invention, the fireproof expansion element faces the upper space, the bracket faces the lower space.

According to an embodiment of the invention, the fireproof expansion element is provided to the bracket or the fireproof expansion element is formed in the bracket.

According to an embodiment of the present invention, the light source device includes a lamp holder and a light emitting portion, the lamp holder is located at an upper portion of the fire prevention device, and the lamp socket corresponds to the perforation of the fire prevention device. Wherein the light emitting portion extends from the lower space to the upper space via the perforation of the fire prevention device, and the light emitting portion is disposed on the socket.

According to an embodiment of the present invention, the light source device includes a lamp holder and a light emitting portion, the lamp holder is held in the perforation of the fire prevention device, wherein the light emitting portion is disposed on the lamp holder And the light emitting portion is located in the lower space.

According to an embodiment of the present invention, the outer side of the bracket of the bracket is disposed on the housing, or the outer side of the bracket of the bracket is formed on the housing, and the bracket is supported The inside of the rack extends from the outside of the bracket toward the light emitting portion, and the heat dissipation passage is formed between the inside of the bracket of the bracket and the light emitting portion.

According to an embodiment of the present invention, the outer side of the bracket of the bracket is disposed on the housing, or the outer side of the bracket of the bracket is formed on the outer casing, and the inner side of the bracket of the bracket Extending from the outside of the bracket to the light emitting portion, wherein the bracket has at least one heat dissipating passage for communicating the lower space and the upper space, such that the heat dissipating duct of the bracket forms the Cooling channel.

According to an embodiment of the invention, the heat dissipation channel is formed between the outside of the bracket of the bracket and the housing.

According to an embodiment of the present invention, the inner side of the bracket of the bracket is disposed on the socket, and the outer side of the bracket of the bracket extends from the inner side of the bracket toward the housing, and The heat dissipation channel is formed between the outside of the bracket of the bracket and the housing.

According to an embodiment of the present invention, the inner side of the bracket of the bracket is disposed on the socket, and the outer side of the bracket of the bracket extends from the inner side of the bracket to the housing, wherein The bracket has at least one heat dissipation passage for communicating the lower space and the upper space such that the heat dissipation passage of the bracket forms the heat dissipation passage.

According to an embodiment of the invention, the heat dissipation channel is formed between the inside of the bracket of the bracket and the socket.

According to an embodiment of the present invention, the bracket has a receiving portion and a heat dissipating portion integrally extending from an inner side of the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion to form an inner heat dissipating portion. The fireproof expansion element is supported by the receiving portion, wherein the receiving portion forms an outer side of the bracket, and the heat radiating portion forms an inner side of the bracket.

According to an embodiment of the present invention, the bracket has a receiving portion and a heat dissipating portion integrally extending outside the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion to form an outer side heat dissipation. The fireproof expansion element is supported by the receiving portion, wherein the receiving portion forms an inner side of the bracket, and the heat radiating portion forms an outer side of the bracket.

According to an embodiment of the present invention, the bracket has a receiving portion and an inner heat dissipating portion and an outer heat dissipating portion integrally extending from the inner side and the outer side of the receiving portion, respectively. The inner heat dissipating portion forms an inner heat dissipating channel, and the fireproof expansion element is supported by the receiving portion, wherein the inner heat dissipating portion forms an inner side of the bracket, and the outer heat dissipating portion forms an outer side of the bracket .

According to an embodiment of the present invention, the bracket has a receiving portion and an inner heat dissipating portion and an outer heat dissipating portion integrally extending from the inner side and the outer side of the receiving portion, respectively. The outer heat dissipation portion forms an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms an outer side of the bracket .

According to an embodiment of the present invention, the bracket has a receiving portion and an inner heat dissipating portion and an outer heat dissipating portion integrally extending from the inner side and the outer side of the receiving portion, respectively. The inner heat dissipating portion is formed to form an inner heat dissipating channel, the heat dissipating channel is disposed on the outer heat dissipating portion to form an outer heat dissipating channel, and the fireproof expansion element is supported by the receiving portion, wherein the inner heat dissipating portion The inside of the bracket is formed, and the outer heat radiating portion forms the outer side of the bracket.

According to an embodiment of the present invention, the outer heat dissipation channel is a heat dissipation through hole or a heat dissipation through groove, and the inner heat dissipation channel is a heat dissipation through hole or a heat dissipation through groove, respectively.

According to an embodiment of the invention, the inner side of the bracket of the bracket is higher than the outer side of the bracket.

According to an embodiment of the invention, the light emitting portion is detachably disposed on the socket.

According to an embodiment of the invention, the lamp housing has a high-end opening that communicates with the interior space.

According to an embodiment of the present invention, the lamp housing device includes a top cover integrally formed at a high end of the housing, or the top cover is disposed at a high end of the housing, wherein The housing has at least one heat dissipation hole, and the heat dissipation hole communicates with the upper space.

According to an embodiment of the invention, the bracket is a steel piece, a cast iron piece or a ceramic piece.

According to an embodiment of the invention, the housing and the bracket are integrally formed steel, cast iron or ceramic pieces.

According to an embodiment of the invention, the housing is a steel piece, a cast iron piece or a ceramic piece.

According to another aspect of the present invention, the present invention further provides an embedded fireproof light fixture, comprising:

a lamp housing device, wherein the lamp housing device comprises a housing, the housing forming a heat transfer passage and having a low end opening communicating with the heat transfer passage;

a light source device, wherein the light source device is disposed in the heat transfer passage, and light generated by the light source device can be radiated to the outside of the embedded fireproof luminaire through the low end opening;

A fire protection apparatus, wherein the fire protection apparatus includes at least one fireproof expansion element retained in the heat transfer passage, and the fireproof expansion element is used to block the heat transfer passage after expansion.

According to another aspect of the present invention, the present invention further provides a fireproof lamp housing, comprising:

a lamp holder

a lamp housing device, wherein the lamp housing device includes a housing having an interior space and a low end opening communicating with the interior space;

a fire prevention device, wherein the fire prevention device has a perforation, wherein the fire prevention device is disposed in the inner space of the casing, and the fire prevention device separates the inner space to form a lower space and an upper space The through hole communicates with the lower space and the upper space, wherein the lamp holder is located in the upper space, wherein the fireproof lamp housing further has at least one heat dissipation channel, and each of the heat dissipation channels respectively communicates with the lower portion a space and the upper space, wherein the fire prevention device encloses each of the heat dissipation passages after expansion to prevent the lower space and the upper space from being communicated by each of the heat dissipation passages.

According to an embodiment of the invention, the fire protection device comprises at least one fireproof expansion element having an expansion element perforation, and the expansion element is perforated to form the perforation of the fire protection device, wherein A fireproof expansion element is retained in the interior space of the housing to separate the interior space to form the lower space and the upper space, wherein the expansion element encloses each of the heat dissipation channels after expansion.

According to an embodiment of the present invention, the fire prevention device includes at least one fireproof expansion element and a bracket, the fireproof expansion element has a perforation of the expansion element, the bracket has a bracket perforation, wherein the fireproof expansion An element is supported by the bracket, and the expansion element perforation and the bracket perforation correspond to each other to form the perforation of the fire protection device, wherein the bracket and the fireproof expansion element are located in the housing The inner space forms the lower space and the upper space to partition the inner space, wherein the expansion element encloses each of the heat dissipation channels after expansion.

According to an embodiment of the invention, the fireproof expansion element faces the upper space, the bracket faces the lower space.

According to an embodiment of the invention, the fireproof expansion element is provided to the bracket or the fireproof expansion element is formed in the bracket.

According to an embodiment of the invention, the socket corresponds to the perforation of the fire protection device.

According to an embodiment of the invention, the socket is held in the perforation of the fire protection device.

According to an embodiment of the invention, the fire protection device is provided to the lamp holder.

According to an embodiment of the present invention, the outer side of the bracket of the bracket is disposed on the housing, or the outer side of the bracket of the bracket is formed on the housing, and the bracket is supported The inside of the frame extends inwardly from the outside of the bracket to define the perforations of the fire protection device by the inside of the bracket of the bracket.

According to an embodiment of the present invention, the inner side of the bracket of the bracket is disposed on the socket, and the outer side of the bracket of the bracket extends from the inner side of the bracket toward the housing, and The heat dissipation channel is formed between the outside of the bracket of the bracket and the housing.

According to an embodiment of the present invention, the inner side of the bracket of the bracket is disposed on the socket, and the outer side of the bracket of the bracket extends from the inner side of the bracket to the housing, wherein The bracket has at least one heat dissipation passage for communicating the lower space and the upper space such that the heat dissipation passage of the bracket forms the heat dissipation passage.

According to an embodiment of the invention, the inner side of the bracket of the bracket is higher than the outer side of the bracket.

According to an embodiment of the present invention, the bracket has a receiving portion and a heat dissipating portion integrally extending from an inner side of the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion to form an inner heat dissipating portion. The fireproof expansion element is supported by the receiving portion, wherein the receiving portion forms an outer side of the bracket, and the heat radiating portion forms an inner side of the bracket.

According to an embodiment of the present invention, the bracket has a receiving portion and a heat dissipating portion integrally extending outside the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion to form an outer side heat dissipation. The fireproof expansion element is supported by the receiving portion, wherein the receiving portion forms an inner side of the bracket, and the heat radiating portion forms an outer side of the bracket.

According to an embodiment of the present invention, the bracket has a receiving portion and an inner heat dissipating portion and an outer heat dissipating portion integrally extending from the inner side and the outer side of the receiving portion, respectively. The inner heat dissipating portion forms an inner heat dissipating channel, and the fireproof expansion element is supported by the receiving portion, wherein the inner heat dissipating portion forms an inner side of the bracket, and the outer heat dissipating portion forms an outer side of the bracket .

According to an embodiment of the present invention, the bracket has a receiving portion and an inner heat dissipating portion and an outer heat dissipating portion integrally extending from the inner side and the outer side of the receiving portion, respectively. The outer heat dissipation portion forms an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms an outer side of the bracket .

According to an embodiment of the present invention, the bracket has a receiving portion and an inner heat dissipating portion and an outer heat dissipating portion integrally extending from the inner side and the outer side of the receiving portion, respectively. The inner heat dissipating portion is formed to form an inner heat dissipating channel, the heat dissipating channel is disposed on the outer heat dissipating portion to form an outer heat dissipating channel, and the fireproof expansion element is supported by the receiving portion, wherein the inner heat dissipating portion The inside of the bracket is formed, and the outer heat radiating portion forms the outer side of the bracket.

According to an embodiment of the invention, the bracket is a steel piece, a cast iron piece or a ceramic piece.

According to an embodiment of the invention, the housing and the bracket are integrally formed steel, cast iron or ceramic pieces.

According to an embodiment of the invention, the housing is a steel piece, a cast iron piece or a ceramic piece.

DRAWINGS

1A is a perspective view of a conventional recessed luminaire.

Figure 1B is a cross-sectional view of the above conventional recessed luminaire.

2A is a perspective view of another conventional recessed luminaire.

2B is a perspective view of the above conventional recessed luminaire.

3 is a schematic view showing an application state of an embedded fireproof light fixture according to a preferred embodiment of the present invention.

4A is a perspective view of a perspective view of the embedded fire protection lamp according to the above preferred embodiment of the present invention.

4B is a perspective view of another perspective view of the embedded fire protection lamp according to the above preferred embodiment of the present invention.

FIG. 5 is a schematic view showing the internal structure of the embedded fireproof lamp according to the above preferred embodiment of the present invention, which is cut along the intermediate position.

FIG. 6 is a schematic view showing the internal structure of the embedded fireproof lamp according to the above preferred embodiment of the present invention.

7A is a schematic view of the fireproof expansion element of the embedded fire protection lamp in an unexpanded state according to the above preferred embodiment of the present invention.

7B is a schematic view of the fireproof expansion element of the embedded fire protection lamp in an expanded state according to the above preferred embodiment of the present invention.

FIG. 8 is a schematic view showing the internal structure of the embedded fireproof lamp according to a modified embodiment of the above preferred embodiment of the present invention taken along the intermediate position.

FIG. 9A is a schematic view showing the internal structure of the embedded fireproof lamp according to another modified embodiment of the present invention, which is cut along the intermediate position.

Figure 9B is a schematic view showing the internal structure of the embedded fire-retardant lamp according to another modified embodiment of the present invention, which is cut along the intermediate position.

FIG. 9C is a schematic view showing the internal structure of the embedded fireproof lamp according to another modified embodiment of the present invention, which is cut along the intermediate position.

Figure 10 is a front elevational view of an embedded fire luminaire in accordance with another preferred embodiment of the present invention.

Figure 11 is a schematic view showing the internal structure of the embedded fireproof lamp according to the above preferred embodiment of the present invention, which is cut along the intermediate position.

Figure 12 is a schematic view showing the internal structure of the embedded fireproof lamp according to the above preferred embodiment of the present invention.

Figure 13 is a front elevational view of the embedded fire protection light fixture in accordance with a variant embodiment of the above preferred embodiment of the present invention.

Fig. 14 is a schematic view showing the internal structure of the embedded fireproof lamp according to the above modified embodiment of the present invention, which is cut along the intermediate position.

Figure 15 is a schematic view showing the internal structure of the embedded fireproof lamp according to the above modified embodiment of the above preferred embodiment of the present invention.

16A is a perspective view of a perspective view of an embedded fire protection luminaire in accordance with another preferred embodiment of the present invention.

Figure 16B is a perspective view of another perspective view of the embedded fire protection lamp in accordance with the above preferred embodiment of the present invention.

Figure 16C is a front elevational view of the embedded fire protection light fixture in accordance with the above-described preferred embodiment of the present invention.

Figure 17 is a schematic view showing the internal structure of the embedded fireproof lamp according to the above preferred embodiment of the present invention taken along the intermediate position.

Figure 18 is a schematic illustration of one application state of the embedded fire protection luminaire in accordance with the above-described preferred embodiment of the present invention.

Detailed ways

The following description is presented to disclose the invention to enable those skilled in the art to practice the invention. The preferred embodiments in the following description are by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention as defined in the following description may be applied to other embodiments, modifications, improvements, equivalents, and other embodiments without departing from the spirit and scope of the invention.

It should be understood by those skilled in the art that in the disclosure of the present invention, the terms "longitudinal", "transverse", "upper", "lower", "front", "back", "left", "right", The orientation or positional relationship of the indications such as "vertical", "horizontal", "top", "bottom", "inside", "outside", etc. is based on the orientation or positional relationship shown in the drawings, which is merely for convenience of description. The above terms are not to be construed as limiting the invention, and are not intended to be a limitation of the invention.

It will be understood that the term "a" is understood to mean "at least one" or "one or more", that is, in one embodiment, the number of one element may be one, and in other embodiments, the element The number can be multiple, and the term "a" cannot be construed as limiting the quantity.

Referring to Figure 3 of the accompanying drawings of the present invention, an embedded fire luminaire in accordance with a preferred embodiment of the present invention is disclosed and illustrated in the following description, wherein the embedded fire luminaire can be embedded The manner in which the luminaire attachment 100 is installed is in a use environment, for example, the luminaire attachment 100 can be, but is not limited to, a ceiling, preferably the luminaire attachment 100 is a fire resistant ceiling. The luminaire attachment 100 is preset with a mounting hole 101 for mounting the embedded fire luminaire. In other words, the embedded fire protection luminaire can be embedded and retained within the mounting aperture 101 of the luminaire attachment 100. The embedded fire protection luminaire is capable of providing light to the environment of use of the lower portion of the luminaire attachment 100 after being energized, such as to provide illumination. And when a fire occurs in the use environment of the lower portion of the lamp attachment 100, the embedded fireproof lamp can prevent or delay the high temperature generated by the fire or the flame spread from the lower space of the lamp attachment 100 to the upper space.

Specifically, referring to FIG. 3 to FIG. 6, the embedded fireproof lamp includes a lamp housing device 10, a light source device 20, and a fire prevention device 30, wherein the light source device 20 and the fire protection device 30 are respectively disposed In the lamp housing device 10.

Further, the lamp housing device 10 includes a housing 11 having a low end 111, a high end 112, an inner space 113, and a low end opening 114, wherein the housing 11 is The low end 111 and the high end 112 correspond to each other, and the low end opening 114 communicates with the inner space 113 at the low end 111. In other words, the low end opening 114 is provided or formed at the lower end 111 of the housing 11 such that the low end opening 114 communicates with the inner space 113 at the lower end 111.

The shape of the housing 11 is not limited in the embedded fireproof luminaire of the present invention, such as in the preferred example of the embedded fire luminaire shown in Figures 3 to 6, The housing 11 may be in a cylindrical shape to form the internal space 113 inside the housing 11, and the lower end 111 of the housing 11 is formed to communicate with the lower end of the internal space 113 Opening 114. In other examples of the embedded fire protection luminaire, the housing 11 may also be, but is not limited to, a hollow ellipsoid or a square cylinder.

Further, the lamp housing device 10 includes a cover 12 having a light passage 121 that penetrates both sides of the cover 12 . Preferably, the light tunnel 121 is a middle through hole, that is, the light tunnel 121 penetrates both sides of the face cover 12 in the middle of the face cover 12. In this preferred example of the embedded fire protection luminaire shown in Figures 3 to 6, the face cover 12 is mounted to the lower end 111 of the housing 11 such that the face cover 12 The light tunnel 121 communicates with the low end opening 114 of the housing 11, and the face cover 12 is mounted after the low end 111 of the housing 11, the cover 12 The outer wall of the housing 11 extends outward. In other words, the face cover 12 protrudes from the outer wall of the housing 11.

In a further example of the embedded fire protection luminaire, the face cover 12 and the housing 11 may also be integrally formed. In other words, the face cover 12 extends outwardly from the outer wall of the housing 11 at the lower end 111 of the housing 11 such that the face cover 12 protrudes from the outer wall of the housing 11.

It should be noted that, in the embedded fireproof luminaire of the present invention, the manner in which the cover 12 is mounted on the lower end 111 of the housing 11 is not limited, for example, but not limited to The face cover 12 is attached to the lower end 111 of the housing 11 by means of screws, rivets or the like.

The lamp housing device 10 further includes at least one mounting spring body 13, wherein each of the mounting spring bodies 13 has a connecting end 131 and a free end 132 corresponding to the connecting end 131, wherein each of the mountings The connecting ends 131 of the spring body 13 are respectively operably disposed to the housing 11 and form a mounting space between the free end 132 of each of the mounting spring bodies 13 and the face cover 12 14. The mounting hole 101 for embedding and retaining the embedded fire protection luminaire in the luminaire attachment 100.

Preferably, the number of the mounting spring bodies 13 is implemented as, but not limited to, two, wherein the two mounting spring bodies 13 are respectively symmetrically disposed on both sides of the housing 11 in such a manner that The embedded fire protection luminaire can be reliably embedded and held in the mounting hole 101 of the luminaire attachment 100 in the subsequent manner. Of course, those skilled in the art should understand that in other possible examples of the embedded fireproof luminaire, the number of the mounting spring bodies 13 may be one, or three or more.

Preferably, the connecting end 131 of the mounting spring body 13 can be embodied as a torsion spring, or the connecting end 131 of the mounting spring body 13 is provided with a torsion spring. The free end 132 of the mounting spring body 13 is adjacent to the face cover 12 or the free end of the mounting spring body 13 when the embedded fire protection luminaire is not mounted to the luminaire attachment 100 132 is attached to the face cover 12. Applying the free end 132 of the mounting spring body 13 and the free end 132 of the mounting spring body 13 during installation of the embedded fire protection luminaire in the luminaire attachment 100 Facing the direction of the high end 112 of the housing 11, at this time, on the one hand, the apparent size of the embedded fireproof luminaire can be reduced to facilitate the majority of the housing 11 and the mounting spring body 13 The mounting hole 101 of the lamp attachment 100 can smoothly pass from the lower portion of the lamp attachment 100 to the upper portion of the lamp attachment 100, and on the other hand, the connection of the mounting spring body 13 The torsion spring of the end 131 is in a deformed state after being stressed. It is worth mentioning that since the size of the face cover 12 is larger than the size of the mounting hole 101 of the lamp attachment 100, the face cover 12 is held at the upper portion of the lamp attachment 100. Then, since the external force acting on the mounting spring body 13 is undone, the torsion spring of the connecting end 131 of the mounting spring body 13 is automatically restored to the initial state, in the process, the mounting of the spring body 13 The free end 132 moves toward the upper direction of the lamp attachment 100 and finally fits over the upper portion of the lamp attachment 100, at which time the freedom of the face cover 12 and the mounting spring body 13 The mounting space 14 is formed between the ends 132, and the luminaire attachment 100 is retained within the mounting space 14 to embed and retain the embedded fire luminaire in the mounting of the luminaire attachment 100 Inside the hole 101.

In other words, when the embedded fireproof luminaire is embedded and held in the mounting hole 101 of the luminaire attachment 100, a clamping force is provided between the cover 12 and the mounting spring body 13 to The embedded fire protection luminaire is securely mounted on the luminaire attachment 100.

It is worth mentioning that when the embedded fireproof luminaire is embedded and held in the mounting hole 101 of the luminaire attachment 100, the cover 12 is attached to the lower portion of the luminaire attachment 100. The lamp attachment 100 is configured to close a gap formed between the lamp attachment 100 and the casing 11 by the cover surface 12, in such a manner that when a lower portion of the lamp attachment 100 occurs In the event of a fire, the high temperature or flame generated by the fire is prevented or delayed from spreading from the lower portion of the lamp attachment 100 to the upper portion via a gap formed between the lamp attachment 100 and the casing 11.

Preferably, a fireproof expansion material may be disposed on an upper portion of the face cover 12, and the embedded fireproof light fixture is disposed on the face when the embedded fireproof light fixture is embedded and held in the mounting hole 101 of the lamp attachment 100 A fireproof expansion material of the upper portion of the cover 12 is held before the face cover 12 and the luminaire attachment 100. The fireproof expansion material automatically expands when it encounters a high temperature or fire generated by a fire to close a gap formed between the face cover 12 and the lamp attachment 100, thereby preventing or delaying the high temperature generated by the fire or the flame through the fire. A gap formed between the lamp attachment 100 and the face cover 12 spreads from a lower portion of the lamp attachment 100 to an upper portion.

Preferably, the housing 11 and the face cover 12 may be made of a high temperature resistant material such as, but not limited to, steel, cast iron, ceramic, etc., so that the housing 11 and the face cover 12 may each be a steel piece. a cast iron piece or a ceramic piece, when the high temperature generated by the fire or the flame acts on the casing 11 and the face cover 12, the casing 11 and the face cover 12 are not deformed or burned. Thereby, the embedded fireproof luminaire is still reliably held in the mounting hole 101 of the luminaire attachment 100, such that the embedded fire luminaire can prevent the high temperature generated by the fire or the flame through the luminaire attachment The mounting hole 101 of 100 is spread from the lower portion of the lamp attachment 100 to the upper portion, or can prevent a high temperature generated by a fire or a flame from passing through a gap formed between the lamp attachment 100 and the case 11. The lower portion of the luminaire attachment 100 spreads to the upper portion.

Referring to FIGS. 3 to 6, the light source device 20 is held in the internal space 113 of the casing 11, and light generated by the light source device 20 after being energized can pass through the casing 11 The light tunnels 121 of the low end opening 114 and the face cover 12 are radiated to the lower portion of the luminaire attachment 100 to provide light for the environment of use, such as, but not limited to, providing illumination.

Preferably, the face cover 12 supports the light source device 20 at a lower portion of the light source device 20 such that the light source device 20 is held in the internal space 113 of the casing 11. For example, the light source device 20 is first disposed in the inner space 113 of the casing 11, and secondly, the face cover 12 is mounted on the lower end 113 of the casing 11, whereby the surface is The cover 12 supports the light source device 20 at a lower portion of the light source device 20, and enables the light source device 20 to be held in the internal space 113 of the casing 11.

More preferably, the face cover 12 has a mounting cavity 122, wherein the mounting cavity 122 communicates with the light tunnel 121, wherein a portion of the light source device 20 can be mounted in the mounting cavity of the face cover 12. In this manner, the light source device 20 is reliably supported by the face cover 12 in such a manner that the face cover 12 can be secured even when the embedded fireproof lamp is shaken or vibrated. The position of the light source device 20 does not change, thereby facilitating the reliability and stability of the embedded fireproof luminaire when it is used.

Further, referring to FIG. 3 to FIG. 6, the light source device 20 includes a lamp holder 21 and a light emitting portion 22, wherein the lamp holder 21 is disposed in the inner space 113 of the lamp housing 11, and The socket 21 can be electrically connected to an external power source, wherein the light emitting portion 22 is disposed on the socket 21, and the free side of the light emitting portion 22 can be mounted to the cover 12 The inside of the cavity 122 is installed so that the light-emitting portion 22 can be supported by the face cover 12, so that the light source device 20 is held in the internal space 113 of the casing 11. When the external power source supplies power to the socket 21, the socket 21 can further supply electric energy to the light emitting portion 22 to generate light by the light emitting portion 22, and the light generated by the light emitting portion 22 can The lower end opening 114 of the housing 11 and the light tunnel 121 of the face cover 12 are radiated to a lower portion of the luminaire attachment 100.

Preferably, the light emitting portion 22 is detachably mounted to the socket 21, so that when the light emitting portion 22 is damaged, or when the light emitting portion 22 cannot meet the needs of the user, the user can Replacing the light-emitting portion 22, in this manner, is advantageous in reducing the use cost of the embedded fire-proof luminaire.

It is worth mentioning that the type of the light-emitting portion 22 is not limited in the embedded fire-proof luminaire of the present invention. For example, the light-emitting portion 22 can be implemented as, but not limited to, an MR16 or GU10 conventional halogen lamp, CFL. Energy-saving lamps, LED GU10 lamps, or LED MR16 lamps.

Further, the lamp body device 10 has a wire passage 15 in which the wire passage 15 communicates with the inner space 113 at the high end 112 of the housing 11, such that a wire 200 can pass through the wire A passage 15 extends from the outside of the housing 11 to the internal space 113 and is electrically connected to the socket 21, so that external electric energy can be supplied to the socket 21 through the electric wire 200, and The socket 21 can further supply electric energy to the light emitting portion 22.

Further, the light emitting portion 22 includes a light cup 221 and a light emitting element 222, and the light emitting element 222 is disposed on the light cup 221 . The lamp cup 221 further includes a mounting body 2211 and a collecting cup 2212 extending from the mounting body 2211. The light emitting element 222 is disposed on the mounting body 2211 of the lamp cup 221 and is held therein. The interior of the concentrating cup 2212 is described. The mounting body 2211 of the lamp cup 221 is detachably mounted to the socket 21, and when the mounting body 2211 of the lamp cup 221 is mounted to the socket 21, the light emitting element The 222 can be automatically electrically connected to the socket 21 through the mounting body 2211. The free side of the concentrating cup 2212 can be mounted in the mounting cavity 122 of the face cover 12 such that the lamp cup 221 of the illuminating portion 22 can be supported by the face cover 12. In other words, the socket 21 can supply electrical energy to the light-emitting element 222 via the mounting body 2211, such that the light-emitting element 222 generates light, and the light generated by the light-emitting element 222 is The light cup 2212 can be condensed and irradiated to the outside of the embedded fireproof luminaire via the low end opening 114 of the casing 11 and the light passage 121 of the cover 12 in sequence.

Referring to FIGS. 3 to 6, the fire prevention device 30 is disposed in the internal space 113 of the casing 11, and the fire prevention device 30 separates the internal space 113 of the casing 11 to form a lower portion. A space 1131 and an upper space 1132, wherein the lower space 1131 of the casing 11 is adjacent to the lower end 111, and the upper space 1132 of the casing 11 is adjacent to the upper end 112.

The embedded fireproof luminaire further has at least one heat dissipation channel 40, wherein each of the heat dissipation channels 40 communicates with the lower space 1131 and the upper space 1132 of the housing 11 respectively to allow the light source device 20 to The heat generated by the lower space 1131 is radiated to the upper space 1132 via each of the heat dissipation passages 40, and heat is radiated to the outside of the embedded fireproof luminaire in the upper space 1132 of the casing 11.

Further, the fire protection device 30 has a through hole 31, wherein the socket 21 of the light source device 20 corresponds to the through hole 31 of the fire prevention device 30. The mounting body 2211 of the lamp cup 221 of the light emitting portion 22 can extend from the lower space 1131 to the upper space 1132 via the through hole 31 of the fire prevention device 30, and is mounted to the lamp a seat 21, at this time, the concentrating cup 2212 of the lamp cup 221 of the light-emitting portion 22 and the light-emitting element 222 of the light-emitting portion 22 are held in the lower space 1131 of the casing 11. And the fire prevention device 30 surrounds the mounting body 2211 of the lamp cup 221. Heat generated by the light emitting element 222 in the lower space 1131 of the housing 11 can be radiated to the upper space 1132 via each of the heat dissipation passages 40, and in the upper space 1132 of the housing 11. Radiation is radiated to the exterior of the embedded fire protection luminaire. When a fire occurs in the lower portion of the luminaire attachment 100, once the high temperature or fire generated by the fire acts on the fire prevention device 30, the fire prevention device 30 can automatically expand to block each of the heat dissipation passages 40, through In this way, the lower space 1131 of the casing 11 and the upper space 1132 can be prevented from communicating, thereby preventing or delaying the high temperature generated by the fire or the flame is attached from the lamp via each of the heat dissipation channels 40. The lower portion of the object 100 spreads to the upper portion.

Still further, the fire protection device 30 has at least one fire expansion element 32, wherein the fire protection expansion element 32 has an expansion element aperture 321 or the fire protection expansion element 32 forms the expansion element aperture 321 . In this example of the embedded fire protection luminaire, the expansion element perforations 321 of the fire resistant expansion element 32 form the perforations 31 of the fire protection device 30.

The fireproof expansion member 32 is held in the internal space 113 of the casing 11 and serves to partition the internal space 113 of the casing 11 to form the lower space 1131 and the upper space 1132. The socket 21 corresponds to the expansion element through hole 321 of the fireproof expansion element 32, and the mounting body 2211 of the lamp cup 221 of the light emitting portion 22 can pass through the through hole 31 of the fire prevention device 30. The lower space 1131 extends from the upper space 1132 and is mounted to the socket 21.

The fire resistant expansion element 32 has an expanded state and a non-expanded state. Under normal circumstances, such as in the absence of a high temperature or fire caused by a fire, the fire-resistant expansion element 32 is in the non-expanded state such that the lower space 1131 of the housing 11 passes through each The heat dissipation channel 40 communicates with the upper space 1132, so that the lower space 1131, each of the heat dissipation channels 40 and the upper space 1132 form a direct and smooth heat transfer channel 300, thereby ensuring the embedded Heat dissipation capability of fire protection luminaires. The fireproof expansion element 32 is automatically switchable from the non-expanded state to the expanded state and blocks each of the heat dissipation channels 40 when a high temperature or fire generated by a fire acts on the fireproof expansion element 32, Further, the lower space 1131 and the upper space 1132 are prevented from communicating, and in this manner, the high temperature generated by the fire or the flame can be prevented from spreading from the lower portion of the lamp attachment 100 to the upper portion via each of the heat dissipation passages 40. .

In other words, when a high temperature or flame generated by a fire acts on the fireproof expansion member 32, the fireproof expansion member 32 can automatically expand and be in the expanded state, and the fireproof expansion member 32 is blocked in an expanded manner. The heat transfer passage 300 is broken to prevent or retard the high temperature generated by the fire or the flame propagates from the lower portion of the luminaire attachment 100 to the upper portion via the heat transfer passage 300.

It will be understood by those skilled in the art that the fireproof expansion element 32 will automatically expand in the expanded state only when subjected to high temperatures or flames generated by a fire, and by closing each of the heat dissipation passages 40. The heat transfer passage 300 is blocked in a manner. In other words, when the heat generated by the light-emitting element 222 of the light-emitting portion 22 of the embedded fire-proof luminaire acts on the fire-proof expansion element 32, the fire-proof expansion element 32 does not expand, in this way, It is beneficial to ensure the reliability and stability of the embedded fireproof luminaire.

Referring to Figures 3 to 6, the fire protection device 30 includes at least one bracket 33, wherein the bracket 33 has a bracket through hole 331, or the bracket 33 forms the bracket through hole 331, wherein A fireproof expansion element 32 is disposed on the bracket 33, or the fireproof expansion element 32 is formed in the bracket 33, and the expansion element perforation 321 of the fireproof expansion element 32 and the bracket 33 are The bracket perforations 331 correspond to each other to form the perforations 31 of the fire protection device 30. The bracket 33 is held in the inner space 113 of the housing 11 for supporting the fireproof expansion element 32 such that the fireproof expansion element 32 can be retained in the housing 11. The internal space 113. The bracket 33 serves to prevent the fireproof expansion member 32 from falling out of the inner space 113 of the housing 11 after expansion, thereby ensuring that the fireproof expansion member 32 can effectively close each after expansion The way of the heat dissipation channel 40 blocks the heat transfer channel 300. In this way, it is advantageous to ensure the reliability and stability of the embedded fireproof luminaire when it is used.

Preferably, the bracket 33 is made of a high temperature resistant material, for example, the refractory material forming the bracket 33 may be, but not limited to, a steel material, a cast iron material, a ceramic material, so that the bracket 33 may be steel. Pieces, cast iron pieces, ceramic pieces, so that when a high temperature generated by a fire or a flame acts on the bracket 33, the bracket 33 does not fall off or deform from the inner space 113 of the casing 11, In this manner, the bracket 33 enables the fireproof expansion member 32 to be reliably held in the internal space 113 of the casing 11.

More preferably, the bracket 33 faces the lower space 1131 of the housing 11, the fireproof expansion element 32 faces the upper space 1132 of the housing 11, so that when the embedded fireproof light fixture is When embedded in and held by the mounting hole 101 of the luminaire attachment 100, the fireproof expansion member 32 can be held at an upper portion of the bracket 33 so that the bracket 33 is used as a support The manner of the fireproof expansion element 32 is such that the fireproof expansion element 32 is retained in the interior space 113 of the housing 11.

Referring to Figures 5 and 6, the bracket 33 has at least one receiving portion 332 and at least one heat dissipating portion 333, wherein the receiving portion 332 and the heat dissipating portion 333 are integrally formed, and the fireproof expansion member 32 The support portion 332 provided to the bracket 33 or the fireproof expansion member 32 is formed in the receiving portion 332 of the bracket 33. That is, the receiving portion 332 of the bracket 33 is a portion covered by the fireproof expansion member 32, and the heat dissipating portion 333 of the bracket 33 is not covered by the fireproof expansion member 32. part.

With reference to FIG. 5 and FIG. 6, the heat dissipation portion 333 has an inner heat dissipation portion 333a and an outer heat dissipation portion 333b, wherein the inner heat dissipation portion 333a and the outer heat dissipation portion 333b extend integrally with the support portion, respectively. The inside and the outside of the portion 332. That is, the receiving portion 332 is formed at a central portion of the bracket 33, and the inner heat radiating portion 333a and the outer heat radiating portion 333b are formed on the inner side and the outer side of the bracket 33, respectively, and the inner side The heat radiating portion 333a is for defining the bracket through hole 331, the outer heat radiating portion 333b is mounted to the casing 11, or the outer heat radiating portion 333b and the casing 11 are integrally formed, thereby making the bracket The frame 33 can be held in the internal space 113 of the housing 11. It should be noted that the manner in which the outer heat dissipation portion 333b of the bracket 33 is mounted to the housing 11 is not limited in the embedded fireproof luminaire of the present invention, for example, by screws and rivets. The outer heat radiating portion 333b of the bracket 33 is attached to the casing 11 in an equal manner.

It is worth mentioning that the housing 11 and the bracket 33 may be integrally formed. Preferably, the housing 11 and the bracket 33 may be integrally formed steel pieces, cast iron pieces or ceramic pieces.

That is, in this example of the embedded fireproof luminaire shown in FIG. 6, the inner heat radiating portion 333a and the outer heat radiating portion 333b of the bracket 33 are not covered by the fireproof expansion member 32. cover.

Further, the bracket 33 has at least one outer heat dissipation channel 334 and at least one inner heat dissipation channel 335, wherein each of the outer heat dissipation channels 334 and each of the inner heat dissipation channels 335 respectively penetrate the two of the brackets 33 On the side, in the following, each of the outer heat dissipation channels 334 and each of the inner heat dissipation channels 335 are used to communicate the lower space 1131 and the upper space 1132 of the housing 11, respectively. That is, each of the outer heat dissipation channels 334 and each of the inner heat dissipation channels 335 of the bracket 33 are used to form the heat dissipation passages 40 of the embedded fireproof light fixture.

Specifically, each of the outer heat dissipation channels 334 is respectively disposed at intervals from the outer heat dissipation portion 333b of the bracket 33, so that each of the outer heat dissipation channels 334 is respectively located at the bracket 33. The outer heat dissipation portion 333b communicates with the lower space 1131 of the casing 11 and the upper space 1132, wherein each of the inner heat dissipation channels 335 is respectively disposed at a distance from the inner side of the bracket 33. a portion 333a such that each of the inner heat dissipation channels 335 communicates with the lower space 1131 and the upper space 1132 of the housing 11 at the inner heat dissipation portion 333a of the bracket 33, respectively. The outer heat dissipation channels 334 and each of the inner heat dissipation channels 335 can respectively form the heat dissipation channels 40 of the embedded fire protection light fixture.

Further, a gap is formed between the inner heat radiating portion 333a of the bracket 33 and the mounting body 2211 of the lamp cup 221 of the light emitting portion 22 to form another heat radiating passage 40.

Preferably, each of the outer heat dissipation channels 334 is implemented as a heat dissipation through hole, and each of the inner heat dissipation channels 335 is implemented as a heat dissipation through groove. Nevertheless, those skilled in the art should understand that in other examples of the embedded fire protection luminaire, each of the outer heat dissipation channels 334 may also be implemented as a heat dissipation channel, and each of the inner heat dissipation channels 335 may also Implemented as a heat dissipation through hole; or each of the outer heat dissipation channels 334 and each of the inner heat dissipation channels 335 are implemented as heat dissipation through holes; or each of the outer heat dissipation channels 334 and each of the inner heat dissipation channels Each of the 335 is implemented as a heat dissipation through slot; or at least one of the outer heat dissipation channels 334 is implemented as a heat dissipation through hole, and the remaining outer heat dissipation channels 334 are implemented as heat dissipation through grooves, and at least one of the inner heat dissipation channels 335 is implemented As the heat dissipation through hole, the remaining inner heat dissipation channel 335 is implemented as a heat dissipation through groove.

Preferably, the bracket 33 may be a stamping member in which each of the inner heat dissipation channels 335 and each of the outer heat dissipation passages 334 are formed while the bracket 33 is formed.

With continued reference to FIGS. 3-6, the luminaire device 10 further includes a top cover 16, wherein the top cover 16 is integrally formed at the high end 112 of the housing 11, or the top cover 16 is disposed At the high end 112 of the housing 11. The wire passage 15 is provided to the top cover 16 such that the wire passage 15 communicates with the inner space 113 of the casing 11 at the high end 112 of the casing 11.

Further, the housing 11 has at least one heat dissipation hole 115, wherein each of the heat dissipation holes 115 communicates with the upper space 1132 of the housing 11 so that heat generated by the light emitting element 222 can pass through each The heat dissipation channel 40 formed by the outer heat dissipation channel 334 and each of the inner heat dissipation channels 335 is radiated from the lower space 1131 to the upper space 1132, and can be further radiated to the embedded via the heat dissipation hole 115. The exterior of the fire protection luminaire. That is, the heat dissipation holes 115 form a part of the heat transfer passage 300.

Preferably, the fireproof expansion element 32 is located on the lower side of the heat dissipation hole 115, and the fireproof expansion element 32 can block the heat transfer passage 300 by closing each of the heat dissipation passages 40, compared to the conventional The embedded luminaire requires the manner in which the fireproof expansion element blocks the louvers after expansion, and the fireproof expansion element 32 of the present invention only needs to close each of the heat dissipation channels 40 having a small size to block the Heat transfer channel 300. The manner in which the embedded fire protection luminaire of the present invention provides for blocking each of the heat dissipation channels 40 has many advantages.

One of the advantages is that the size of the heat dissipation holes 115 of the housing 11 can be greatly increased to effectively improve the heat dissipation performance of the embedded fireproof luminaire. For example, the heat dissipation holes 115 may extend from the cover 16 to a position where the bracket 33 is located.

The second advantage is that the fireproof expansion element 32 can close each of the heat dissipation channels 40 only after a high temperature or flame generated by a fire, and only a small expansion is required, so that the fireproof expansion element 32 is allowed to have a low The material with a double expansion coefficient is made, which is advantageous for greatly reducing the manufacturing cost of the embedded fireproof luminaire, thereby facilitating the large-scale application and popularization of the embedded fire luminaire.

The third advantage is that the fire-proof expansion element 32 only needs to close the heat-dissipating channel 40 of a smaller size after expansion, and the embedding of the utility model is required to close a large-sized heat dissipation hole after expansion. The fire protection luminaire provides only that the fire damper element 32 is more reliable to enclose the smaller size of the heat dissipation passage 40 after expansion. In other words, it is more difficult to close the small-sized heat dissipation passage 40 after the fire-proof expansion member 32 is expanded, and the difficulty of closing the large-sized heat dissipation hole is made, and the fire-proof expansion member 32 is closed after expansion. The reliability of the heat dissipation channel 40 is much higher than the reliability of the closed large size heat dissipation hole.

Figure 6 shows the state of the embedded fire luminaire when it is in normal use, at which time the fire-resistant expansion element 32 of the fire protection device 30 is in the non-expanded state, the light-emitting element 222 is in the Heat generated by the lower space 1131 of the housing 11 can be radiated from the lower space 1131 to the upper space via the heat dissipation passages 40 formed by each of the outer heat dissipation channels 334 and each of the inner heat dissipation channels 335 After 1132, it can be further radiated to the outside of the embedded fireproof luminaire via the heat dissipation holes 115. That is, the lower space 1131, each of the heat dissipation channels 40, the upper space 1132, and the heat dissipation holes 115 can form a direct and smooth heat transfer passage 300, thereby ensuring the embedded fire prevention. The heat dissipation capability of the luminaire.

7A and 7B show the principle of fire prevention of the embedded fireproof luminaire, when a fire occurs in the lower portion of the luminaire attachment 100, a high temperature or flame generated by the fire is in the lower space 1131 of the casing 11. Acting on the fireproof expansion element 32, at this time, the fireproof expansion element 32 can be automatically expanded and in the expanded state, and the expanded fireproof expansion element 32 can automatically close each of the outer heat dissipation channels 334. And each of the heat dissipation passages 40 formed by each of the inner heat dissipation channels 335 to block the heat transfer passage 300, in such a manner, can prevent or delay the high temperature generated by the fire or the fire through the heat transfer passage 300 spreads from the lower portion of the luminaire attachment 100 to the upper portion.

According to another aspect of the present invention, the present invention further provides a fireproof lamp housing, wherein the fireproof lamp housing includes the lamp body device 10, the fire prevention device 30, and the lamp holder 21, the fireproof lamp housing The structure of the lamp body device 10, the fire prevention device 30 and the lamp holder 21 and the relationship between them and the lamp body device 10 of the embedded fire protection lamp shown in FIGS. 3 to 6 The structure of the fire prevention device 30 and the lamp holder 21 and the relationship between them are identical.

Figure 8 shows a variant embodiment of the embedded fire protection luminaire, which differs from the embedded fire protection luminaire shown in Figures 3 to 6 in the embedded fire luminaire shown in Figure 8 In the preferred embodiment, the top cover 16 further has at least one top cover through hole 161, wherein the top cover through hole 161 communicates with the upper space 1132 of the housing 11 and the exterior of the embedded fireproof light fixture In this way, the heat dissipation performance of the embedded fireproof luminaire can be further improved.

Figure 9A shows a variant embodiment of the embedded fire protection luminaire, which differs from the embedded fire protection luminaire shown in Figures 3 to 6 in the embedded fire protection shown in Figure 9A. In this preferred example of the luminaire, the bracket 33 has an integrally formed one of the carrying portion 332 and one of the heat dissipating portions 333, wherein the carrying portion 332 of the bracket 33 is located at the heat dissipating portion 333 The outer side, and the heat dissipating portion 333 is for defining the bracket through hole 331, wherein the fireproof expansion member 32 is disposed on the carrying portion 332, or the fireproof expansion member 32 is formed on the carrying portion 332, thereby The bearing portion 332 of the bracket 33 can be used to support the fireproof expansion element 32 to enable the fireproof expansion element 32 to be retained in the interior space 113 of the housing 11.

The bearing portion 332 of the bracket 33 is disposed on the housing 11 , or the bearing portion 332 of the bracket 33 is formed on the housing 11 , wherein the heat dissipation portion 333 is self-supporting The portion 332 extends toward the mounting body 2211 of the lamp cup 221 of the light emitting portion 22, and has a gap between the heat dissipating portion 333 and the mounting body 2211 to form the embedded fireproof lamp. The heat dissipation channel 40, wherein the heat dissipation channel 40 is configured to communicate with the lower space 1131 and the upper space 1132 of the housing 11.

Preferably, the bracket 33 further has at least one inner heat dissipation channel 335, and each of the inner heat dissipation channels 335 is respectively disposed at a distance from the heat dissipation portion 333 of the bracket 33, and each of the brackets The inner heat dissipation channels 335 respectively extend through the two sides of the bracket 33, wherein the inner heat dissipation channels 335 form each of the heat dissipation channels 40 of the embedded fireproof light fixture for the communication of the housing 11 A lower space 1131 and the upper space 1132.

When a high temperature or flame generated by a fire occurring in a lower portion of the luminaire attachment 100 acts on the fireproof expansion member 32, the fireproof expansion member 32 can be automatically expanded to be in the expanded state, and the expanded state A fireproof expansion element 32 is used to enclose each of the heat dissipation passages 40 to block the heat transfer passage 300, thereby preventing or retarding the high temperature generated by the fire or the flame from the lower portion of the luminaire attachment 100 via the heat transfer passage 300. Spread to the top.

Figure 9B shows another variant embodiment of the embedded fire protection luminaire, which differs from the embedded fire protection luminaire shown in Figures 3 to 6 in the embedded embodiment shown in Figure 9B. In this preferred example of the fire protection luminaire, the bracket 33 has an integrally formed one of the carrying portion 332 and one of the heat dissipating portions 333, wherein the heat dissipating portion 333 of the bracket 33 is located at the carrying portion 332. The outer side, and the receiving portion 332 is used to define the bracket perforation 331, wherein the fireproof expansion element 32 is disposed on the bearing portion 332, or the fireproof expansion element 32 is formed on the bearing portion 332 Thus, the carrier portion 332 of the bracket 33 can be used to support the fire resistant expansion element 32 to enable the fire resistant expansion element 32 to be retained in the interior space 113 of the housing 11.

The heat dissipating portion 333 of the bracket 33 is disposed on the casing 11, or the heat dissipating portion 333 of the bracket 22 is formed in the casing 11, wherein the receiving portion 332 is from the The heat radiating portion 333 extends toward the mounting body 2211 of the lamp cup 221 of the light emitting portion 22, and has a gap between the receiving portion 332 and the mounting body 2211 to form the embedded fireproof The heat dissipation channel 40 of the luminaire, wherein the heat dissipation channel 40 is configured to communicate with the lower space 1131 and the upper space 1132 of the housing 11.

Preferably, the bracket 33 further has at least one outer heat dissipation channel 334, and each of the outer heat dissipation channels 334 is respectively disposed at a distance from the heat dissipation portion 333 of the bracket 33, and each of the brackets 33 The outer heat dissipation channels 334 respectively extend through the two sides of the bracket 33, wherein the outer heat dissipation channels 334 form each of the heat dissipation channels 40 of the embedded fireproof light fixture for communicating with the housing 11 A lower space 1131 and the upper space 1132.

When a high temperature or flame generated by a fire occurring in a lower portion of the luminaire attachment 100 acts on the fireproof expansion member 32, the fireproof expansion member 32 can be automatically expanded to be in the expanded state, and the expanded state A fireproof expansion element 32 is used to enclose each of the heat dissipation passages 40 to block the heat transfer passage 300, thereby preventing or retarding the high temperature generated by the fire or the flame from the lower portion of the luminaire attachment 100 via the heat transfer passage 300. Spread to the top.

Figure 9C shows another variant embodiment of the embedded fire protection luminaire, which differs from the embedded fire luminaire shown in Figure 9B in the embedded fire luminaire shown in Figure 9C. In the preferred embodiment, the bracket 33 has at least one notch 337, wherein each of the notches 337 is spaced apart from the heat dissipating portion 333 of the bracket 33 so that each of the notches 337 can Each of the heat dissipation passages 40 for communicating the lower space 1131 of the casing 11 and the upper space 1132 is formed between the casing 11 and the bracket 33, by being able to Further improving the heat dissipation effect of the embedded fireproof luminaire.

Referring to Figures 10 to 12 of the accompanying drawings of the present invention, an embedded fire protection luminaire according to another preferred embodiment of the present invention is illustrated in the following description, and Figures 3 to 6 show The embedded fire protection luminaire differs from that in the embedded fire protection luminaire shown in Figures 10 to 12, the fire protection device 30A includes at least one fireproof expansion element 32A and a bracket 33A and has a The perforation 31A, wherein the fireproof expansion member 32A has an expansion member perforation 321A and at least one expansion member passage 320A, wherein the bracket 33A has a bracket perforation 331A and at least one bracket passage 330A, wherein the fireproof expansion member 32A is overlappedly disposed on the bracket 33A, or the fireproof expansion member 32A is formed in the bracket 33A, and the expansion member through hole 321A of the fireproof expansion member 32A corresponds to the bracket 33A a bracket through hole 331A to form the through hole 31A of the fire prevention device 30A, wherein each of the expansion element passages 320A of the fireproof expansion member 32A corresponds to each of the bracket passages 320A of the bracket 33A To Each of the heat dissipation channels 40 of the embedded fire protection luminaire is formed.

The bracket 33A has a bracket outer side 339A and a bracket inner side 338A corresponding to the bracket outer side 339A, wherein the bracket outer side 339A of the bracket 33A is disposed in the housing 11, or The bracket outer side 339A of the bracket 33A is integrally formed with the housing 11 such that the bracket 33A is held in the inner space 113A of the housing 11, and the bracket 33A The bracket inner side 338A extends from the bracket outer side 339A toward the socket 21 of the light source device 20, and has a gap between the bracket 33A and the socket 21 to form a The heat dissipation passage 40 of the embedded fireproof luminaire, wherein the heat dissipation passage 40 communicates with the lower space 1131 and the upper space 1132 formed at a lower portion and an upper portion of the fire prevention device 30A.

Each of the bracket passages 330A of the bracket 33A are independent of each other, and each of the bracket passages 330A is respectively at the bracket outer side 339A and the bracket inner side 338A of the bracket 33A. Extended between. Correspondingly, the size and shape of the expansion element passage 320A of the fireproof expansion member 32A coincide with the size and shape of the bracket passage 330A of the bracket 33A, thereby corresponding to the bracket passages corresponding to each other. The heat dissipation passage 40 formed by the 330A and the expansion member passage 320A communicates with the lower space 1131 and the upper space 1132 of the housing 11.

Preferably, the bracket 33A extends obliquely inside the housing 11, for example, the bracket outer side 339A of the bracket 33A may be held at the heat dissipation hole 115 of the housing 11. a lower portion, and the bracket inner side 338A may extend to the top of the socket 21 of the light source device 20 such that the bracket inner side 338A of the bracket 33A is higher than the outer side of the bracket The height at which the 339A is located, in this manner, facilitates increasing the size of the bracket passage 330A of the bracket 33A and the expansion member passage 320A of the fireproof expansion member 32A to enhance the embedded fire luminaire Cooling effect.

More preferably, the bracket inner side 338A of the bracket 33A is located at a height higher than the bracket outer side 339A, so that the longitudinal cross section of the bracket 33A has a substantially truncated cone shape. Not only is it convenient to replace the light-emitting portion 22, but also the heat generated by the light-emitting portion 22 in the lower space 1131 of the casing 11 is quickly attached to the casing via each of the heat-dissipating passages 40. The upper space 1132 of the 11 and further radiated to the exterior of the embedded fire luminaire via the louvers 115 of the housing 11.

Figures 13 to 15 show a variant embodiment of the embedded fire protection luminaire, which differs from the embedded fire protection luminaire shown in Figures 10 to 12 in Figures 13 to 15 In the preferred example of the embedded fire protection luminaire, the bracket inner side 338A of the bracket 33A is disposed on the socket 21 of the light source device 20, whereby the socket 21 is The bracket 33A is held in the inner space 113 of the casing 11, and the fireproof expansion member 32A is further held in the inner space 113 of the casing 11. The bracket outer side 339A of the bracket 33A extends from the bracket inner side 338A toward the housing 11 and is capable of having a gap between the bracket outer side 339A and the housing 11 to form The heat dissipation channel 40, wherein the heat dissipation channel 40 communicates with the lower space 1131 and the upper space 1132 of the housing 11.

Referring to Figures 16A through 18 of the accompanying drawings of the present invention, an embedded fire luminaire in accordance with another preferred embodiment of the present invention is illustrated in the following description, wherein the embedded fire luminaire includes A lamp housing device 10', a light source device 20', and a fire protection device 30', wherein the light source device 20' and the fire protection device 30' are respectively disposed on the lamp housing device 10'.

Further, the lamp housing device 10' includes a housing 11', wherein the housing 11' has a low end 111', a high end 112', an inner space 113', a low end opening 114', and a a high-end opening 116', the lower end 111' of the housing 11' and the high end 112' correspond to each other, and the low-end opening 114' communicates with the inner space 113' at the low end 111', The high end opening 116' is in communication with the interior space 113' at the high end 112'. In other words, the low end opening 114' is provided or formed on the lower end 111' of the housing 11', and the high end opening 116' is provided in or formed on the housing 11' The high end 112' such that the low end opening 114' and the high end opening 116' communicate with the inner space 113' at the low end 111' and the high end 112' of the housing 11', respectively. .

The lamp housing unit 10' includes a cover 12' having a light passage 121' extending through both sides of the cover 12'. Preferably, the light tunnel 121' is a central perforation, i.e., the light tunnel 121' extends through the sides of the face cover 12' in the middle of the face cover 12'. In this preferred example of the embedded fire protection luminaire shown in Figures 16A through 17, the face cover 12' is mounted to the lower end 111' of the housing 11' such that The light tunnel 121' of the face cover 12' communicates with the low end opening 114' of the housing 11', and the face cover 12' is mounted to the lower end 111 of the housing 11' After that, the face cover 12' extends outwardly from the outer wall of the housing 11'. In other words, the face cover 12' protrudes from the outer wall of the housing 11'.

In a further example of the embedded fire protection luminaire, the face cover 12' and the housing 11' may also be integrally formed. In other words, the face cover 12' extends outwardly from the outer wall of the housing 11' at the lower end 111' of the housing 11' such that the cover 12' protrudes from the housing The outer wall of the 11'.

It should be noted that, in the embedded fireproof luminaire of the present invention, the manner in which the cover 12' is mounted to the lower end 111' of the housing 11' is not limited, for example, However, the face cover 12' is attached to the lower end 111' of the casing 11' not limited to screws, rivets or the like.

The lamp housing device 10' further includes at least one mounting spring body 13', wherein each of the mounting spring bodies 13' has a connecting end 131' and a free end 132' corresponding to the connecting end 131', The connecting end 131' of each of the mounting spring bodies 13' is operably disposed to the housing 11', respectively, and at the free end 132' of each of the mounting spring bodies 13' and An installation space 14' is formed between the face covers 12' for embedding and retaining the embedded fireproof luminaire in the mounting hole 101' of the luminaire attachment 100'.

Preferably, the number of the mounting spring bodies 13' is implemented as, but not limited to, two, wherein two of the mounting spring bodies 13' are symmetrically disposed on opposite sides of the housing 11', respectively. In a manner, the embedded fire luminaire can be reliably embedded and held in the mounting hole 101' of the luminaire attachment 100'. Of course, those skilled in the art will appreciate that in other possible examples of the embedded fire protection luminaire, the number of mounting spring bodies 13' may be one, or more than three.

More preferably, a fireproof expansion material may be disposed at an upper portion of the face cover 12', and is disposed when the embedded fireproof light fixture is embedded and held in the mounting hole 101' of the lamp attachment 100'. A fireproof expansion material at an upper portion of the face cover 12' is held before the face cover 12' and the luminaire attachment 100'. The fireproof expansion material automatically expands when it encounters a high temperature or fire generated by a fire to close a gap formed between the face cover 12' and the lamp attachment 100', thereby preventing or delaying the high temperature generated by the fire or The flame propagates from the lower portion of the lamp attachment 100' to the upper portion via a gap formed between the lamp attachment 100' and the face cover 12'.

Preferably, the housing 11' and the face cover 12' may be made of a high temperature resistant material such as, but not limited to, steel, ceramics, etc., when a high temperature or flame generated by a fire acts on the housing 11' and the When the cover 12' is described, the housing 11' and the cover 12' are also not deformed and burned, so that the embedded fireproof luminaire is still reliably held at the luminaire attachment 100. In the mounting hole 101' of the ', such that the embedded fireproof luminaire can prevent the high temperature generated by the fire or the fire from the luminaire attachment 100' via the mounting hole 101' of the luminaire attachment 100' The lower part spreads to the upper part.

With continued reference to FIGS. 16A through 17, the light source device 20' includes a socket 21' and a light emitting portion 22', wherein the light emitting portion 22' is disposed on the socket 21', and the light emitting portion The free side of 22' is mounted to the face cover 12' such that the light emitting portion 22' can be supported by the face cover 12', thereby causing the light emitting portion 22' by the face cover 12' Being held in the inner space 113' of the housing 11', the lamp holder 21' is located outside the housing 11', thus facilitating rapid heat dissipation of the embedded fireproof luminaire, thereby greatly The heat dissipation performance of the embedded fireproof luminaire is improved. In addition, the high end 112' of the housing 11' is an open structure, so that the embedded fireproof luminaire can provide a direct and smooth heat transfer passage 300' for generating the light emitting portion 22'. The heat is quickly radiated to the outside of the embedded fire protection luminaire. When the external power source supplies power to the socket 21', the socket 21' can further supply electric energy to the light emitting portion 22' to generate light by the light emitting portion 22', and the light emitting portion 22 The generated light can be radiated to the lower portion of the luminaire attachment 100' via the low end opening 114' of the housing 11' and the light passage 121' of the cover 12'.

Preferably, the light emitting portion 22' is detachably mounted to the socket 21', so that when the light emitting portion 22' is damaged, or when the light emitting portion 22' is unable to meet the user's use requirements The user can replace the light emitting portion 22', and in this way, it is advantageous to reduce the use cost of the embedded fireproof light fixture.

It is worth mentioning that the type of the light-emitting portion 22 ′ is not limited in the embedded fire-proof luminaire of the present invention. For example, the light-emitting portion 22 ′ can be implemented as, but not limited to, a conventional halogen lamp of MR16 or GU10. , CFL energy-saving lamps, LED GU10 lamps, or LED MR16 lamps.

Further, the light emitting portion 22' includes a light cup 221' and a light emitting element 222', and the light emitting element 222' is disposed on the light cup 221'. The lamp cup 221' further includes a mounting body 2211' and a collecting cup 2212' extending from the mounting body 2211'. The light emitting element 222' is disposed on the mounting body of the lamp cup 221'. 2211' and is held inside the concentrating cup 2212'. The mounting body 2211' of the lamp cup 221' is detachably mounted to the socket 21', and the mounting body 2211' of the lamp cup 221' is mounted to the socket 21' The light-emitting element 222' can be automatically electrically connected to the socket 21' through the mounting body 2211'. The free side of the concentrating cup 2212' can be mounted in the mounting cavity 122' of the face cover 12' such that the lamp cup 221' of the illuminating portion 22' can be covered by the cover 12' support. In other words, the socket 21' can provide electrical energy to the light-emitting element 222' via the mounting body 2211' to cause the light-emitting element 222' to generate light, and the light generated by the light-emitting element 222' After being condensed by the concentrating cup 2212 ′, the light can be sequentially radiated to the embedded via the low end opening 114 ′ of the housing 11 ′ and the light passage 121 ′ of the cover 12 ′. The exterior of the fire protection luminaire.

Referring to Figures 16A through 17, the fire prevention device 30' is disposed in the internal space 113' of the casing 11'. Preferably, the fire protection device 30' is retained at the high end opening 116' of the housing 11'. It can be understood that in this embodiment of the embedded fireproof luminaire, the fire protection device 30' can also partition the internal space 113' to form a lower space 1131' and an upper space 1132', wherein The lower space 1131' and the upper space 1132' are in communication with each other, and heat generated by the light-emitting element 222' of the light-emitting portion 22' can be radiated from the lower space 1131' to the upper space 1132', and further radiated To the outside of the embedded fire protection luminaire. Preferably, since the high end 112' of the lamp envelope 11' is an open high end, the heat dissipation capability of the embedded fireproof luminaire is greatly improved.

The embedded fireproof luminaire further has at least one heat dissipation channel 40', wherein each of the heat dissipation channels 40' communicates with the inner space 113' of the housing 11' and the exterior of the embedded fireproof luminaire, respectively, The heat generated by the light-emitting element 222' is allowed to radiate from the interior space 113' to the exterior of the embedded fire protection luminaire via the radiant channel 40'. Optionally, the heat dissipation channel 40 ′ is configured to communicate the lower space 1131 ′ and the upper space 1132 ′ to allow heat generated by the light emitting element 222 ′ from the lower space via the heat dissipation channel 40 ′ 1131' radiates to the upper space 1132'.

Further, the fire protection device 30' has a perforation 31', wherein the socket 21' of the light source device 20' corresponds to the perforation 31' of the fire protection device 30'. The mounting body 2211' of the lamp cup 221' of the light emitting portion 22' can extend from the inner space 113' of the housing 11' to the through hole 31' of the fire prevention device 30' to The exterior of the embedded fireproof luminaire is mounted on the socket 21'. At this time, the concentrating cup 2212' of the lamp cup 221' of the illuminating portion 22' and the illuminating portion 22 The light-emitting element 222' is held in the inner space 113' of the casing 11', and the fire prevention device 30' surrounds the mounting body 2211' of the lamp cup 221'. Heat generated by the light-emitting element 222' in the interior space 113' of the housing 11' can be radiated to the exterior of the embedded fire protection luminaire via each of the heat dissipation channels 40'. When a fire occurs in the lower portion of the luminaire attachment 100', once the high temperature or fire generated by the fire acts on the fire prevention device 30', the fire prevention device 30' can automatically expand to block each of the heat dissipation channels. 40', in such a manner, the inner space 113' of the casing 11' can be prevented from communicating with the embedded fireproof lamp, thereby preventing or delaying the high temperature generated by the fire or the flame through each of the heat dissipation The passage 40' propagates from the lower portion of the luminaire attachment 100' to the upper portion.

Furthermore, the fire protection device 30' has at least one fireproof expansion element 32', wherein the fire protection expansion element 32' has an expansion element perforation 321 ', or the fire protection expansion element 32' forms the expansion element perforation 321 '. In this example of the embedded fire protection luminaire, the expansion element perforations 321' of the fire resistant expansion element 32' form the perforations 31' of the fire protection device 30'.

The fire resistant expansion element 32' is retained in the high end opening 116' of the housing 11' and the fire resistant expansion element 32' has an expanded state and a non-expanded state. Preferably, the fire resistant expansion element 32' is located in the interior space 113' of the housing 11' and is retained at the high end opening 116' of the housing 11'. Of course, it can be understood by those skilled in the art that the fireproof expansion element 32' may also be located in the middle of the inner space 113' of the housing 11', and the embedded fireproof light fixture of the present invention is here. There are no restrictions on aspects.

Under normal circumstances, such as in the absence of a high temperature or fire caused by a fire, the fire-resistant expansion element 32' is in the non-expanded state to pass the interior space 113' of the housing 11' Each of the heat dissipation channels 40' communicates with an exterior of the embedded fire protection luminaire such that the internal space 113' and each of the heat dissipation channels 40' form a direct and smooth heat transfer passage 300'. To ensure the heat dissipation capability of the embedded fire protection luminaire. The fireproof expansion element 32' is automatically switchable from the non-expanded state to the expanded state and blocks each of the heat dissipation channels when a high temperature generated by a fire or a flame acts on the fireproof expansion element 32' 40', thereby preventing the internal space 113' from communicating with the embedded fireproof luminaire, in such a manner, it is possible to prevent or delay the high temperature generated by the fire or the flame from the luminaire attachment via each of the heat dissipation passages 40' The lower part of the 100' spreads to the upper part.

In other words, when a high temperature or flame generated by a fire acts on the fireproof expansion element 32', the fireproof expansion element 32' can automatically expand in the expanded state and block the heat transfer in an expanded manner. The passage 300' prevents or retards the high temperature generated by the fire or the flame propagates from the lower portion of the luminaire attachment 100' to the upper portion via the heat transfer passage 300'.

It will be understood by those skilled in the art that the fireproof expansion element 32' will automatically expand in the expanded state only when subjected to a high temperature or flame generated by a fire, and by enclosing each of the heat dissipation passages 40. The way of blocking the heat transfer passage 300'. In other words, when the heat generated by the light-emitting element 222' of the light-emitting portion 22' of the embedded fire-proof luminaire acts on the fire-proof expansion element 32', the fire-proof expansion element 32' does not expand, passing In this way, it is beneficial to ensure the reliability and stability of the embedded fireproof luminaire.

Referring to Figures 16A through 17, the fire protection device 30' includes at least one bracket 33', wherein the bracket 33' has a bracket perforation 331', or the bracket 33' forms a bracket perforation 331 ', wherein the fireproof expansion element 32' is disposed to the bracket 33', and the expansion element perforation 321' of the fireproof expansion element 32' and the bracket perforation 331 of the bracket 33' The perforations 31' of the fire protection device 30' are formed to correspond to each other. The bracket 33' is retained in the high end opening 116' of the housing 11' for supporting the fire resistant expansion element 32' such that the fire resistant expansion element 32' can be retained The high end opening 116' of the housing 11'. In a further example, the bracket 33' may also be retained in the interior space 113' of the housing 11'. The bracket 33' is for preventing the fireproof expansion member 32' from falling off from the high end opening 116' of the housing 11' after expansion, thereby ensuring that the fireproof expansion member 32' can be effectively expanded after expansion The heat transfer passage 300' is blocked in such a manner as to close each of the heat dissipation passages 40'. In this way, it is advantageous to ensure the reliability and stability of the embedded fireproof luminaire when it is used.

Preferably, the bracket 33' is made of a high temperature resistant material, for example, the high temperature resistant material of the bracket 33' may be, but not limited to, a steel material or a ceramic material, so that when a fire generates a high temperature or a flame The bracket 33' does not fall off or deform from the high-end opening 116' of the housing 11' when the bracket 33' is in such a manner that the bracket 33' enables the The fireproof expansion element 32' is securely retained in the high end opening 116' of the housing 11'.

More preferably, the bracket 33' faces the inner space 113' of the housing 11', the fireproof expansion element 32' faces the exterior of the housing 11', so that when the embedded fireproof light fixture is When the mounting hole 101' is embedded in and held by the lamp attachment 100', the fireproof expansion member 32' can be held at an upper portion of the bracket 33' so that the bracket 33 is The fire-resistant expansion element 32' is held in the high-end opening 116' of the housing 11' in a manner that supports the fire-resistant expansion element 32'.

Referring to Figure 17, the bracket 33' has at least one receiving portion 332' and at least one heat dissipating portion 333', wherein the receiving portion 332' and the heat dissipating portion 333' are integrally formed, and the fireproof expansion The element 32' is disposed on the receiving portion 332' of the bracket 33', or the fireproof expansion member 32' is formed in the receiving portion 332' of the bracket 33'. That is, the receiving portion 332' of the bracket 33' is a portion covered by the fireproof expansion member 32', and the heat dissipation portion 333' of the bracket 33' is not described. The portion covered by the fireproof expansion element 32'.

With reference to FIG. 17, the heat dissipation portion 333' has an inner heat dissipation portion 333a' and an outer heat dissipation portion 333b', wherein the inner heat dissipation portion 333a' and the outer heat dissipation portion 333b' extend integrally with the outer heat dissipation portion 333b' The inside and the outside of the receiving portion 332'. That is, the receiving portion 332' is formed in the middle of the bracket 33', and the inner heat radiating portion 333a' and the outer heat radiating portion 333b' are formed on the inner side and the outer side of the bracket 33', respectively. And the inner heat dissipation portion 333a' is for defining the bracket through hole 331', the outer heat dissipation portion 333b' is mounted to the housing 11', or the outer heat dissipation portion 333b' and the housing 11' is integrally formed such that the bracket 33' can be held at the high end opening 116' of the housing 11'. It is to be noted that the manner in which the outer heat dissipation portion 333b' of the bracket 33' is mounted to the housing 11' is not limited in the embedded fireproof luminaire of the present invention, for example, The outer heat radiating portion 333b' of the bracket 33' is attached to the casing 11' by means of a screw, a rivet or the like.

That is, in this example of the embedded fireproof luminaire shown in FIG. 17, the inner heat radiating portion 333a' and the outer heat radiating portion 333b' of the bracket 33' are not protected by the fire. The expansion element 32' is covered.

Further, the bracket 33' has at least one outer heat dissipation channel 334' and at least one inner heat dissipation channel 335', wherein each of the outer heat dissipation channels 334' and each of the inner heat dissipation channels 335' penetrates through On both sides of the bracket 33', in the following, each of the outer heat dissipation channels 334' and each of the inner heat dissipation channels 335' are respectively used to communicate the inner space 113' of the housing 11' and The exterior of the embedded fire protection luminaire. That is, each of the outer heat dissipation channels 334' and each of the inner heat dissipation channels 335' of the bracket 33' are used to form the heat dissipation passage 40' of the embedded fireproof light fixture.

Specifically, each of the outer heat dissipation channels 334' are respectively spaced apart from each other at the outer heat dissipation portion 333b' of the bracket 33', so that each of the outer heat dissipation channels 334' is respectively at the support The outer heat dissipation portion 333b' of the frame 33' communicates with the inner space 113' of the housing 11' and the exterior of the embedded fireproof light fixture, wherein each of the inner heat dissipation channels 335' are spaced apart from each other The inner heat dissipation portion 333a' of the bracket 33' is disposed such that each of the inner heat dissipation channels 335' communicates with the housing 11' at the inner heat dissipation portion 333a' of the bracket 33'. The interior space 113' and the exterior of the embedded fire protection luminaire, and thus each of the outer heat dissipation channels 334' and each of the inner heat dissipation channels 335' can respectively form the heat dissipation of the embedded fire protection luminaire Channel 40'.

In addition, a gap is formed between the inner heat dissipation portion 333a' of the bracket 33' and the mounting body 2211' of the lamp cup 221' of the light emitting portion 22' to form another heat dissipation. Channel 40'.

Preferably, each of the outer heat dissipation channels 334' is implemented as a heat dissipation through hole, and each of the inner heat dissipation channels 335' is implemented as a heat dissipation through groove. Nonetheless, it will be understood by those skilled in the art that in other examples of the embedded fire protection luminaire, each of the outer heat dissipation channels 334' may also be implemented as a heat dissipation channel, each of the inner heat dissipation channels 335' It may also be implemented as a heat dissipation through hole; or each of the outer heat dissipation channels 334' and each of the inner heat dissipation channels 335' may be implemented as heat dissipation through holes; or each of the outer heat dissipation channels 334' and each The inner heat dissipation channels 335' are each implemented as a heat dissipation through groove; or at least one of the outer heat dissipation channels 334' is implemented as a heat dissipation through hole, and the remaining outer heat dissipation channels 334' are implemented as heat dissipation through grooves, at least one The inner heat dissipation channel 335' is implemented as a heat dissipation through hole, and the remaining inner heat dissipation channel 335' is implemented as a heat dissipation through groove.

Preferably, the bracket 33' may be a stamping member in which each of the inner heat dissipation passages 335' and each of the outer heat dissipation passages 334 are formed while the brackets 33' are formed.

In addition, the embedded fireproof light fixture may further include a junction box 50' and a bracket 60', one end of the bracket 60' is disposed on the housing 11', and the junction box 50' is disposed on The other end of the bracket 60', wherein a wire 200 can extend from the junction box 50' to the socket 21' for subsequent supply of electrical energy from the junction box 50' to the Lamp holder 21'. Preferably, the stent holder 60' may be, but not limited to, an "L" shape.

When the fireproof expansion element 32' is in the non-expanded state, heat generated by the light emitting element 222' in the internal space 113' of the housing 11' can be via each of the outer heat dissipation channels 334' The heat dissipation passage 40' formed with each of the inner heat dissipation passages 335' radiates from the inner space 113' to the outside of the embedded fireproof luminaire. When a fire occurs in the lower portion of the luminaire attachment 100', a high temperature or fire generated by the fire acts on the fireproof expansion member 32' in the internal space 113' of the casing 11'. At this time, the fire prevention The expansion element 32' is automatically expandable to be in the expanded state, and the expanded fireproof expansion element 32' is capable of automatically closing each of the outer heat dissipation channels 334' and each of the inner heat dissipation channels 335' The heat dissipation passage 40' blocks the heat transfer passage 300'. In this manner, it is possible to prevent or delay the high temperature generated by the fire or the flame from the fixture attachment 100' via the heat transfer passage 300'. The lower part spreads to the upper part.

It will be understood by those skilled in the art that the above embodiments are merely examples, and the features of the different embodiments may be combined with each other to obtain an embodiment which is easily conceived according to the disclosure of the present invention but is not explicitly indicated in the drawings. .

Those skilled in the art should understand that the embodiments of the present invention described in the above description and the accompanying drawings are only by way of example and not limitation. The object of the invention has been achieved completely and efficiently. The function and structural principle of the present invention have been shown and described in the embodiments, and the embodiments of the present invention may be modified or modified without departing from the principles.

Claims (75)

An embedded fire protection lamp characterized by comprising: a lamp housing device, wherein the lamp housing device comprises a housing having an inner space and a low end opening communicating with the inner space; a light source device, wherein the light source device is disposed in the inner space of the housing, and light generated by the light source device is radiated from the inner space to the chamber via the low end opening of the housing The exterior of the embedded fire luminaire; a fire prevention device, wherein the fire prevention device is disposed in the inner space of the casing, and the fire prevention device separates the inner space to form a lower space and an upper space; wherein the embedded fireproof lamp further Having at least one heat dissipation channel, each of the heat dissipation channels respectively communicating the lower space and the upper space to allow heat generated by the light source device to radiate from the lower space to the upper portion via each of the heat dissipation channels a space, wherein the fire prevention device encloses each of the heat dissipation passages after expansion to prevent the lower space and the upper space from being communicated by each of the heat dissipation passages. The embedded fire protection lamp of claim 1 wherein said fire protection device has a perforation that communicates said lower space and said upper space, wherein said light source means passes through and is retained in said fire protection device The perforations. The embedded fire protection luminaire of claim 2 wherein said fire protection means comprises at least one fire expansion element, said fire protection expansion element having an expansion element perforation, and said expansion element perforation forming said perforation of said fire protection means Wherein the fireproof expansion element is retained in the interior space of the housing to separate the interior space to form the lower space and the upper space, wherein the expansion element encloses each after expansion Describe the heat dissipation channel. The embedded fire protection luminaire of claim 2 wherein said fire protection means comprises at least one fire expansion element and a bracket, said fire protection expansion element having an expansion element perforation, said bracket having a bracket perforation, wherein The fireproof expansion element is supported by the bracket, and the expansion element perforation and the bracket perforation correspond to each other to form the perforation of the fire protection device, wherein the bracket and the fireproof expansion element are located The inner space of the housing forms the lower space and the upper space to partition the inner space, wherein the expansion element encloses each of the heat dissipation channels after expansion. The embedded fire protection light fixture of claim 4 wherein said fire resistant expansion element faces said upper space and said bracket faces said lower space. The embedded fire protection light fixture of claim 4 wherein said fire resistant expansion element is disposed on said bracket or said fire resistant expansion element is formed in said bracket. The embedded fireproof light fixture according to claim 4, wherein said light source means comprises a socket and a light emitting portion, said socket is located at an upper portion of said fire prevention device, and said socket corresponds to said fire prevention device The perforation, wherein the light emitting portion extends from the lower space to the upper space via the perforation of the fire prevention device, and the light emitting portion is disposed at the socket. The embedded fireproof light fixture according to claim 4, wherein said light source means comprises a socket and a light emitting portion, said socket being held by said perforation of said fire prevention means, wherein said light emitting portion is disposed at The lamp holder, and the light emitting portion is located in the lower space. The embedded fireproof luminaire according to claim 7, wherein a bracket outer side of the bracket is provided to the housing, or an outer side of the bracket of the bracket is formed in the housing, and The inside of the bracket of the bracket extends from the outside of the bracket toward the light emitting portion, and the heat dissipation passage is formed between the inside of the bracket of the bracket and the light emitting portion. The embedded fireproof luminaire according to claim 7, wherein a bracket outer side of the bracket is provided to the housing, or a bracket outer side of the bracket is formed in the housing, and the bracket The inside of the bracket extends from the outside of the bracket to the light emitting portion, wherein the bracket has at least one heat dissipating passage for communicating the lower space and the upper space, thereby dissipating the heat of the bracket The track forms the heat dissipation channel. The embedded fire protection light fixture of claim 9, wherein the heat dissipation passage is formed between the outside of the bracket of the bracket and the housing. The embedded fire protection light fixture of claim 10, wherein the heat dissipation passage is formed between the outside of the bracket of the bracket and the housing. The embedded fireproof light fixture according to claim 8, wherein a bracket inner side of the bracket is disposed on the socket, and a bracket outer side of the bracket is from the inner side of the bracket toward the housing Extending, and forming the heat dissipation channel between the outside of the bracket of the bracket and the housing. The embedded fireproof light fixture of claim 8, wherein a bracket inner side of the bracket is disposed on the socket, and a bracket outer side of the bracket extends from the inside of the bracket to the housing Wherein the bracket has at least one heat dissipation passage for communicating the lower space and the upper space such that the heat dissipation passage of the bracket forms the heat dissipation passage. The embedded fire protection luminaire of claim 13 wherein said heat dissipation passage is formed between said inside of said bracket and said socket. The embedded fire protection light fixture of claim 14, wherein the heat dissipation passage is formed between the inside of the bracket of the bracket and the socket. The embedded fireproof luminaire according to claim 10, wherein the bracket has a receiving portion and a heat dissipating portion integrally extending from an inner side of the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion An inner heat dissipating channel is formed, the fireproof expansion element being supported by the receiving portion, wherein the receiving portion forms an outer side of the bracket, and the heat dissipating portion forms an inner side of the bracket. The embedded fireproof luminaire according to claim 12, wherein the bracket has a receiving portion and a heat dissipating portion integrally extending from an inner side of the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion An inner heat dissipating channel is formed, the fireproof expansion element being supported by the receiving portion, wherein the receiving portion forms an outer side of the bracket, and the heat dissipating portion forms an inner side of the bracket. The embedded fireproof luminaire according to claim 14, wherein the bracket has a receiving portion and a heat dissipating portion integrally extending from an inner side of the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion An inner heat dissipating channel is formed, the fireproof expansion element being supported by the receiving portion, wherein the receiving portion forms an outer side of the bracket, and the heat dissipating portion forms an inner side of the bracket. The embedded fireproof luminaire according to claim 16, wherein the bracket has a receiving portion and a heat dissipating portion integrally extending from an inner side of the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion An inner heat dissipating channel is formed, the fireproof expansion element being supported by the receiving portion, wherein the receiving portion forms an outer side of the bracket, and the heat dissipating portion forms an inner side of the bracket. The embedded fireproof luminaire according to claim 10, wherein the bracket has a receiving portion and a heat dissipating portion integrally extending outside the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion An outer heat dissipating channel is formed, the fireproof expansion element being supported by the receiving portion, wherein the receiving portion forms an inner side of the bracket, and the heat dissipating portion forms an outer side of the bracket. The embedded fireproof light fixture according to claim 12, wherein the bracket has a receiving portion and a heat dissipating portion integrally extending outside the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion An outer heat dissipating channel is formed, the fireproof expansion element being supported by the receiving portion, wherein the receiving portion forms an inner side of the bracket, and the heat dissipating portion forms an outer side of the bracket. The embedded fireproof luminaire according to claim 14, wherein the bracket has a receiving portion and a heat dissipating portion integrally extending outside the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion An outer heat dissipating channel is formed, the fireproof expansion element being supported by the receiving portion, wherein the receiving portion forms an inner side of the bracket, and the heat dissipating portion forms an outer side of the bracket. The embedded fireproof luminaire according to claim 16, wherein the bracket has a receiving portion and a heat dissipating portion integrally extending outside the receiving portion, and the heat dissipating passage is disposed at the heat dissipating portion An outer heat dissipating channel is formed, the fireproof expansion element being supported by the receiving portion, wherein the receiving portion forms an inner side of the bracket, and the heat dissipating portion forms an outer side of the bracket. The embedded fireproof light fixture according to claim 10, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms a The outside of the bracket. The embedded fireproof luminaire according to claim 12, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms a The outside of the bracket. The embedded fireproof luminaire according to claim 14, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms a The outside of the bracket. The embedded fireproof light fixture according to claim 16, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms a The outside of the bracket. The embedded fireproof light fixture according to claim 10, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms a The outside of the bracket. The embedded fireproof luminaire according to claim 12, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms a The outside of the bracket. The embedded fireproof luminaire according to claim 14, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms a The outside of the bracket. The embedded fireproof light fixture according to claim 16, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms a The outside of the bracket. The embedded fireproof light fixture according to claim 10, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, and the heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the support portion. The inner heat radiating portion forms the inner side of the bracket, and the outer heat radiating portion forms the outer side of the bracket. The embedded fireproof luminaire according to claim 12, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, and the heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the support portion. The inner heat radiating portion forms the inner side of the bracket, and the outer heat radiating portion forms the outer side of the bracket. The embedded fireproof luminaire according to claim 14, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, and the heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the support portion. The inner heat radiating portion forms the inner side of the bracket, and the outer heat radiating portion forms the outer side of the bracket. The embedded fireproof light fixture according to claim 16, wherein the bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of the receiving portion, The heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, and the heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the support portion. The inner heat radiating portion forms the inner side of the bracket, and the outer heat radiating portion forms the outer side of the bracket. The embedded fire protection lamp of claim 33, wherein the outer heat dissipation channel is a heat dissipation through hole or a heat dissipation through groove, and the inner heat dissipation channel is a heat dissipation through hole or a heat dissipation through groove, respectively. The embedded fire protection light fixture of claim 13 wherein said bracket inner side of said bracket is higher than said bracket outer side. The embedded fireproof light fixture according to any one of claims 7 to 38, wherein the light emitting portion is detachably provided to the socket. The embedded fire protection luminaire according to any one of claims 1 to 38, wherein the lamp housing has a high end opening, and the high end opening communicates with the inner space. The embedded fireproof light fixture according to any one of claims 1 to 38, wherein said lamp housing means comprises a top cover integrally formed at a high end of said housing, or said top cover is provided At a high end of the housing, the housing has at least one heat dissipation hole, and the heat dissipation hole communicates with the upper space. A built-in fire protection light fixture according to any one of claims 4 to 38, wherein the bracket is a steel piece, a cast iron piece or a ceramic piece. A built-in fire protection light fixture according to any one of claims 4 to 38, wherein the housing and the bracket are integrally formed steel, cast iron or ceramic pieces. The embedded fire protection luminaire according to any one of claims 1 to 38, wherein the housing is a steel piece, a cast iron piece or a ceramic piece. The embedded fire protection light fixture of claim 39, wherein the housing is a steel piece, a cast iron piece, or a ceramic piece. The embedded fire protection light fixture of claim 40 wherein the housing is a steel piece, a cast iron piece or a ceramic piece. The embedded fire protection light fixture of claim 41 wherein the housing is a steel piece, a cast iron piece or a ceramic piece. The embedded fire protection light fixture of claim 42 wherein said housing is a steel piece, a cast iron piece or a ceramic piece. The embedded fire protection light fixture of claim 43 wherein the housing is a steel piece, a cast iron piece or a ceramic piece. 50. An embedded fireproof lamp, characterized in that: a lamp housing device, wherein the lamp housing device comprises a housing, the housing forming a heat transfer passage and having a low end opening communicating with the heat transfer passage; a light source device, wherein the light source device is disposed in the heat transfer passage, and light generated by the light source device can be radiated to the outside of the embedded fireproof luminaire through the low end opening; A fire protection device, wherein the fire protection device includes at least one fireproof expansion element that is retained in the heat transfer passage and that is used to block the heat transfer passage after expansion. A fireproof lamp housing, characterized in that it comprises: a lamp holder a lamp housing device, wherein the lamp housing device includes a housing having an interior space and a low end opening communicating with the interior space; a fire prevention device, wherein the fire prevention device has a perforation, wherein the fire prevention device is disposed in the inner space of the casing, and the fire prevention device separates the inner space to form a lower space and an upper space The through hole communicates with the lower space and the upper space, wherein the lamp holder is located in the upper space, wherein the fireproof lamp housing further has at least one heat dissipation channel, and each of the heat dissipation channels respectively communicates with the lower portion a space and the upper space, wherein the fire prevention device encloses each of the heat dissipation passages after expansion to prevent the lower space and the upper space from being communicated by each of the heat dissipation passages. A fire protection lamp envelope according to claim 51, wherein said fire protection means comprises at least one fireproof expansion element having an expansion element perforation, and said expansion element is perforated to form said perforation of said fire protection means, Wherein the fireproof expansion element is held in the inner space of the casing to separate the inner space to form the lower space and the upper space, wherein the expansion element encloses each of the expansion elements after expansion Cooling channel. A fire protection lamp envelope according to claim 51, wherein said fire prevention means comprises at least one fireproof expansion member and a bracket, said fireproof expansion member having an expansion member perforation, said bracket having a bracket perforation, wherein The fire expansion element is supported by the bracket, and the expansion element perforation and the bracket perforation correspond to each other to form the perforation of the fire protection device, wherein the bracket and the fireproof expansion element are located The inner space of the housing forms the lower space and the upper space to partition the inner space, wherein the expansion element encloses each of the heat dissipation channels after expansion. A fire protection lamp envelope according to claim 53, wherein said fireproof expansion member faces said upper space, said bracket faces said lower space. A fire protection lamp envelope according to claim 53, wherein said fireproof expansion member is provided to said bracket, or said fireproof expansion member is formed in said bracket. A fire protection lamp envelope according to claim 53, wherein said socket corresponds to said perforation of said fire protection device. A fire protection lamp envelope according to claim 53, wherein the socket is held in said perforation of said fire protection means. A fire protection lamp envelope according to claim 53, wherein said fire prevention means is provided to said socket. A fireproof lamp envelope according to claim 56, wherein a bracket outer side of said bracket is provided to said housing, or said bracket outer side of said bracket is formed in said housing, and said tray The inside of the bracket of the rack extends inwardly from the outside of the bracket to define the perforations of the fire protection device by the inside of the bracket of the bracket. A fireproof lamp envelope according to claim 58, wherein a bracket inner side of said bracket is provided to said socket, and a bracket outer side of said bracket extends from said bracket inner side toward said housing direction And forming the heat dissipation passage between the outside of the bracket of the bracket and the housing. A fire protection lamp envelope according to claim 59, wherein an inner side of the bracket of the bracket is disposed on the socket, and an outer side of the bracket of the bracket extends from the inner side of the bracket to the housing, Wherein the bracket has at least one heat dissipation passage for communicating the lower space and the upper space, so that the heat dissipation channel of the bracket forms the heat dissipation passage. A fire protection lamp envelope according to claim 60, wherein said bracket inner side of said bracket is higher than said bracket outer side. A fireproof lamp envelope according to claim 59, wherein said bracket has a receiving portion and a heat radiating portion integrally extending from an inner side of said receiving portion, said heat dissipating passage being provided at said heat radiating portion to form An inner heat dissipating passage, the fireproof expansion member being supported by the receiving portion, wherein the receiving portion forms an outer side of the bracket, and the heat dissipating portion forms an inner side of the bracket. The fireproof lamp envelope according to claim 60, wherein said bracket has a receiving portion and a heat radiating portion integrally extending to an inner side of said receiving portion, said heat dissipating passage being provided at said heat radiating portion to form An inner heat dissipating passage, the fireproof expansion member being supported by the receiving portion, wherein the receiving portion forms an outer side of the bracket, and the heat dissipating portion forms an inner side of the bracket. A fireproof lamp envelope according to claim 59, wherein said bracket has a receiving portion and a heat radiating portion integrally extending outside said receiving portion, said heat dissipating passage being provided at said heat radiating portion to form An outer heat dissipation channel, the fireproof expansion member is supported by the receiving portion, wherein the receiving portion forms an inner side of the bracket, and the heat dissipation portion forms an outer side of the bracket. A fireproof lamp envelope according to claim 60, wherein said bracket has a receiving portion and a heat radiating portion integrally extending outside said receiving portion, said heat dissipating passage being provided at said heat radiating portion to form An outer heat dissipation channel, the fireproof expansion member is supported by the receiving portion, wherein the receiving portion forms an inner side of the bracket, and the heat dissipation portion forms an outer side of the bracket. A fireproof lamp envelope according to claim 59, wherein said bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of said receiving portion, said heat dissipation The inner heat dissipation portion is disposed to form an inner heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms the Outside the bracket. A fireproof lamp envelope according to claim 60, wherein said bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of said receiving portion, said heat dissipation The inner heat dissipation portion is disposed to form an inner heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms the Outside the bracket. A fireproof lamp envelope according to claim 59, wherein said bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of said receiving portion, said heat dissipation The outer heat dissipation portion is disposed to form an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms the Outside the bracket. A fireproof lamp envelope according to claim 60, wherein said bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of said receiving portion, said heat dissipation The outer heat dissipation portion is disposed to form an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein the inner heat dissipation portion forms an inner side of the bracket, and the outer heat dissipation portion forms the Outside the bracket. A fireproof lamp envelope according to claim 59, wherein said bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of said receiving portion, said heat dissipation a heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, the heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein The inner heat radiating portion forms the inner side of the bracket, and the outer heat radiating portion forms the outer side of the bracket. A fireproof lamp envelope according to claim 60, wherein said bracket has a receiving portion and an inner heat radiating portion and an outer heat radiating portion integrally extending integrally from the inner side and the outer side of said receiving portion, said heat dissipation a heat dissipation channel is disposed on the inner heat dissipation portion to form an inner heat dissipation channel, the heat dissipation channel is disposed on the outer heat dissipation portion to form an outer heat dissipation channel, and the fireproof expansion member is supported by the receiving portion, wherein The inner heat radiating portion forms the inner side of the bracket, and the outer heat radiating portion forms the outer side of the bracket. A fireproof lamp envelope according to any one of claims 53 to 72, wherein the bracket is a steel piece, a cast iron piece or a ceramic piece. A fireproof lamp envelope according to any one of claims 53 to 72, wherein said housing and said bracket are integrally formed steel pieces, cast iron pieces or ceramic pieces. A fireproof lamp envelope according to any one of claims 51 to 72, wherein the casing is a steel piece, a cast iron piece or a ceramic piece. A fire protection lamp envelope according to claim 73, wherein said housing is a steel piece, a cast iron piece or a ceramic piece.

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