TW201618698A - Cooling cup - Google Patents

Abstract

A cooling cup includes a cup body and a plurality of heat pipes thermal connected to the cup body. Each heat pipe includes a vapouring end and a condensing end. The vapouring end is arranged on an outside surface of the cup body. The condensing end extends from the vapouring end and away from the cup body. The condensing end is connected to a cooling element.

Description

Quick cold cup

The invention relates to a cooling device, in particular to a quick cooling cup.

With the accelerated pace of life and the improvement of the quality of life, people's control over their living time is becoming more and more strict, and the requirements for convenience of living are getting higher and higher. People often encounter the need to quickly cool liquids with higher temperatures. . For example, when people need to drink water, pour boiling water into a traditional cup that carries drinking water. Because the temperature of boiling water is too high to drink immediately, it takes a long time to wait for boiling water to cool before drinking.

In order to accelerate the cooling rate of liquids, a variety of quick-cooling appliances for rapid cooling of high-temperature liquids have appeared on the market, and are generally washed with a cryogenic liquid to achieve cooling, but the cooling efficiency is low and the cooling rate is slow. In addition, the built-in cooling medium can also be used for cooling purposes, but the cooling efficiency still cannot meet the demand, and must be supplemented by the cooling medium to ensure the cooling effect, which is limited by the use time and the number of uses.

SUMMARY OF THE INVENTION The present invention is directed to a quick-cooling cup to solve the problem of low cooling efficiency of the quick-cooling appliance and limitation of the time of use and the number of uses.

A quick cooling cup comprising a cup body and at least one heat pipe thermally coupled to the cup body, the heat pipe comprising an evaporation section and a condensation section. The evaporation section is disposed on an outer surface of the cup body, and the condensation section extends from the evaporation section toward a direction away from the outer surface of the cup body and is connected to a heat dissipation component.

The quick cooling cup provided by the present invention is provided with a heat pipe thermally connected thereto on the cup body, an evaporation section of the heat pipe is disposed on an outer surface of the cup body, and the condensation section is away from the evaporation section toward the cup body. The direction of the outer surface extends and is connected to a heat dissipating component, which improves the heat dissipation efficiency of the quick cooling cup, so that the liquid contained in the quick cooling cup is rapidly cooled, and at the same time, the quick cooling cup provided by the invention can be permanently used. The effect does not diminish with the time of use and the number of uses.

Figure 1 is an exploded view of the quick cooling cup of the present invention.

Figure 2 is an exploded view of another angle of the quick cooling cup shown in Figure 1.

3 is a schematic view of the quick cooling cup of FIG. 1.

The invention will be further described in detail below with reference to the accompanying drawings.

Referring to FIGS. 1-3, a quick cooling cup 10 in an embodiment of the present invention includes a cup body 100 and a heat pipe 200 thermally coupled to the cup body 100.

The cup 100 includes an outer surface 106. The outer surface 106 is a bottom wall 101 and a peripheral wall 102 surrounding the bottom wall 101. The peripheral wall 102 is a cylindrical structure having an upper end opening 103 and a lower end opening 104. The bottom wall 101 is disposed and sealed to the lower end opening 104 of the peripheral wall 102. The bottom wall 101 can be a planar structure or a curved structure. In the present embodiment, the bottom wall 101 is a curved surface which is protruded from the lower end opening 104 of the peripheral wall 102 in a direction away from the upper end opening 103. The connection between the bottom wall 101 and the peripheral wall 102 is smoothly transitioned to enhance the convenience when the heat pipe 200 is attached.

The cup 100 may be made of a material having good thermal conductivity, such as a metal material. Corrosion-resistant materials, such as stainless steel or ceramics, may be provided on the inner surface 105 of the cup 100 to reduce contamination of the contained liquid by the materials employed by the cup 100 during use.

The heat pipe 200 has an evaporation section 201 and a condensation section 202. The evaporation section 201 is provided on the outer surface 106 of the cup 100. The condensation section 202 extends from the evaporation section 201 in a direction away from the cup 100 and is coupled to the heat dissipation assembly 300.

The evaporation section 201 extends from the upper end opening 103 of the cup 100 to the lower end opening 104 and then to the bottom wall 101. In the present embodiment, the heat pipe 200 is disposed on the outer surface 106 of the cup 100 along the height direction of the cup 100, that is, the portion of the evaporation section 201 extending from the upper end opening 103 of the cup 100 to the lower end opening 104 is a straight line. Type to reduce the heat transfer path to enhance heat dissipation efficiency. Of course, in other embodiments, the evaporation section 201 may also be S-shaped, diagonally-shaped, or wound around the outer surface 106 of the cup 100. The evaporation section 201 of the heat pipe 200 is flat, which increases the contact area of the evaporation section 201 with the cup 100, and at the same time increases the convenience of attaching the heat pipe 200 to the cup 100. A thermal conductive adhesive may be added to the portion of the evaporation section 201 that is in contact with the cup 100 to enhance the thermal connection performance of the evaporation section 201 and the cup 100, thereby improving heat dissipation efficiency. In some other embodiments, the evaporation section 201 can also be embedded in the cup 100 (not shown) to increase the contact area between the evaporation section 201 and the cup 100, thereby improving heat dissipation efficiency.

The condensation section 202 extends away from the cup 100 to dissipate heat absorbed by the evaporation section 201 from the cup 100. In the present embodiment, the condensation section 202 may be cylindrical. The condensation section 202 is disposed vertically downward from the bottom wall 101 of the cup 100 to improve assembly performance with the heat dissipation assembly 300. In other embodiments, the condensation section 202 can also be designed in other shapes.

The number of the heat pipes 200 can be flexibly set according to the capacity of the cup 100. In the present embodiment, the number of the heat pipes 200 is four, and is evenly distributed on the outer surface 106 of the cup 100. The evaporation section 201 of the heat pipe 200 is flat, and the condensation section 202 is cylindrical. In the manufacturing process, the heat pipe 200 in which the evaporation section 201 and the condensation section 202 are both cylindrical is first selected, and then the evaporation section 201 is subjected to a flattening operation to obtain the heat pipe 200 used in the embodiment. It can be understood that the heat pipe 200 can also be formed by other manufacturing processes.

Inside the heat pipe 200 is a pipe sealed with a working medium. The working medium may be water, ethanol or the like. The pipe is a vacuum chamber and maintains a certain degree of vacuum, and the gas pressure is less than atmospheric pressure, so that the vaporization temperature of the working medium is lowered, and thus the vaporization amount and the vaporization speed are both improved.

After the evaporation section 201 of the heat pipe 200 absorbs heat, the liquid working medium in the evaporation section 201 is heated and vaporized, and the vaporized working medium diffuses to the condensation section 202 away from the cup 100 to conduct heat to the condensation section 202. The connected heat sink assembly 300, the working medium temperature drops and condenses into a liquid state in the condensation section 202, releasing heat, thereby dissipating heat to the cup 100. Further, the heat pipe 200 may be filled with a mesh, fibrous or granular filler, and a capillary structure is formed in the heat pipe 200 to increase the circulation of the liquid working medium formed after the condensation of the condensation section 202 to the evaporation section 201. The reflux speed, in turn, increases the cooling efficiency of the quick cooling cup 10.

The quick cooling cup 10 provided by the present invention is provided with a heat pipe 200 thermally connected thereto on the cup body 100. The evaporation section 201 of the heat pipe 200 is disposed on the outer surface 106 of the cup body 100, and the condensation section 202 is self-owned. The evaporation section 201 extends away from the outer surface 106 of the cup 100 and is connected to a heat dissipating component 300. The heat dissipation efficiency is high, and the liquid contained in the quick cooling cup 10 is rapidly cooled. Meanwhile, the present invention provides The heat dissipation effect of the quick cooling cup 10 is not limited by the use time and the number of uses.

The heat dissipation assembly 300 of the quick cooling cup 10 provided by the present invention includes a heat dissipation block 301. The heat dissipation block 301 is thermally connected to the plurality of heat pipes 200. The heat dissipation block 301 is disposed below the bottom wall 101 of the cup 100. The heat dissipation block 301 is provided with a joint portion 303. The joint portion 303 is a through hole corresponding to the number of the heat pipes 200. The condensation section 202 of the heat pipe 200 is inserted into the joint portion 303 and is thermally connected to the joint portion 303. In order to enhance the thermal continuity of the condensation section 202 and the joint portion 303, a thermal conductive paste (not shown) may be added between the two. The heat dissipation assembly 300 further includes a bottom plate 304 covering one side of the joint portion 303 to protect the heat pipe 200 inserted therein. In some other embodiments, the joint portion 303 can also be a blind hole. The heat dissipation assembly 300 further includes a plurality of heat dissipation fins 302. The fins 302 are divergently disposed around the heat dissipation block 301.

The quick cooling cup 10 provided by the present invention may further include a cup sleeve 400. The cup sleeve 400 is sleeved with the cup body 100 and the heat pipe 200 to protect the cup body 100 and the heat pipe 200, and also increases the aesthetics of the quick cooling cup 10 provided by the present invention. In the present embodiment, the cup sleeve 400 is a cylindrical structure having an upper end opening 401 and a lower end opening 402. The upper end opening 401 is connected to the upper end opening 103 of the cup 100. Specifically, the upper end opening 103 of the cup 100 is provided with a flange 107 which is equivalent to the diameter of the upper end opening 401 of the cup 400, so that the flange 107 and the upper end opening 401 of the cup 400 are opened. connection. The flange 107 is a curved structure extending upward and outward from the upper end opening 103 of the cup 100. When the liquid is poured outward from the quick cooling cup 10, the flange 107 acts to guide the liquid to prevent the liquid from flowing. It flows out along the outer surface of the cup 400 to the lower end opening 402, which increases the cleanliness of the quick-cooling cup 10, and at the same time, after the liquid is poured, the outer and bottom portions of the quick-cooling cup 10 are wiped off by using a paper towel or a rag. The trouble with liquid stains. The cup sleeve 400 is provided with a plurality of vents 403 to enhance the air flow in the cup sleeve 400 and increase heat dissipation efficiency. The vent 403 is disposed adjacent to the lower end opening 402. The plurality of vents 403 are evenly arranged on the periphery of the lower end opening 402 of the cup 400.

Each of the fins 302 extends from the heat sink block 301 toward the vent 403 of the cup sleeve 400. The fins 302 are spaced apart from each other to increase the heat dissipation area and enhance heat dissipation performance. In this embodiment, the fins 302 all extend to the vent 403 and are connected to the inner surface of the cup 400 to increase the stability of the quick-cooling cup 10, and part of the heat can also be transferred from the fin 302 to the quick-cooling cup. The cup sleeve 400 of 10 further enhances the heat dissipation efficiency of the quick cooling cup 10. In other embodiments (not shown), the fins 302 may also be disposed separately from the cup sleeve 400 to increase the air circulation efficiency in the cup sleeve 400 and enhance the heat dissipation effect. In addition, the fins 302 may also be partially separated from the cup sleeve 400, and the other portion extends to the vent 403 and connected to the inner surface of the cup sleeve 400 to balance the air circulation efficiency in the cup sleeve 400 and the quick cooling cup 10 The heat is transferred from the fins 302 to the cup 400 of the quick cooling cup 10 and is radiated to the external environment, which enhances the heat dissipation efficiency of the quick cooling cup 10.

In other embodiments, the cup sleeve 400 can also be a cup-like structure that differs from the cylindrical structure in that it includes a bottom portion (not shown). The bottom portion is connected to the lower end opening 402 of the tubular structure to reduce the influence of dust entering between the cup 100 and the cup 400 on the heat dissipation effect of the quick cooling cup 10, and at the same time increase the aesthetics of the quick cooling cup 10. The condensation section 202 of the heat pipe 200 can extend directly to the bottom of the cup 400 and be attached thereto to further dissipate heat from the condensation section 202.

The quick cooling cup 10 provided by the present invention may further include a handle 500. The handle 500 is disposed outside the cup sleeve 400 to enhance the convenience of the user when holding the quick cooling cup 10.

The quick cooling cup 10 provided by the present invention may further include a cup cover 600. The lid 600 is placed over the upper end opening 103 of the cup 100 to prevent debris and dust from falling into the cup 100. The lid 600 includes a lid portion 601 and a mating portion 602 connected to a side of the lid portion 601. In the present embodiment, the outer side of the engaging portion 602 is provided with an external thread 603, and the inner surface 105 of the cup 100 is provided with an internal thread 108 that cooperates with the external thread 603. In other embodiments, the engaging portion 602 can also be coupled to the cup sleeve 400 in a snap-fit manner (not shown). In addition, the cup cover 600 further includes a sealing ring 604 sleeved on the fitting portion 602 to enhance the tightness of the quick cooling cup 10.

The technical and technical features of the present invention have been disclosed as above, and those skilled in the art can still make various substitutions and modifications without departing from the spirit and scope of the invention. Therefore, the scope of the present invention should be construed as being limited by the scope of the appended claims

10‧‧‧Speed cold cup

100‧‧‧ cup body

101‧‧‧ bottom wall

102‧‧‧Weibi

103‧‧‧Upper opening

104‧‧‧Bottom opening

105‧‧‧ inner surface

106‧‧‧Outer surface

107‧‧‧Flange

108‧‧‧ internal thread

200‧‧‧ heat pipe

201‧‧‧Evaporation section

202‧‧‧Condensation section

300‧‧‧Heat components

301‧‧‧Heat block

302‧‧‧Fins

303‧‧‧Combination Department

304‧‧‧floor

400‧‧‧ cup sets

401‧‧‧Upper open mouth

402‧‧‧Lower open mouth

403‧‧‧ vents

500‧‧‧handle

600‧‧ ‧ cup lid

601‧‧‧ 盖部

602‧‧‧ Matching Department

603‧‧‧ external thread

604‧‧‧ sealing ring

no

10‧‧‧Speed cold cup

100‧‧‧ cup body

101‧‧‧ bottom wall

103‧‧‧Upper opening

104‧‧‧Bottom opening

105‧‧‧ inner surface

106‧‧‧Outer surface

107‧‧‧Flange

108‧‧‧ internal thread

200‧‧‧ heat pipe

201‧‧‧Evaporation section

202‧‧‧Condensation section

300‧‧‧Heat components

301‧‧‧Heat block

302‧‧‧Fins

303‧‧‧Combination Department

304‧‧‧floor

400‧‧‧ cup sets

401‧‧‧Upper open mouth

402‧‧‧Lower open mouth

403‧‧‧ vents

500‧‧‧handle

600‧‧ ‧ cup lid

601‧‧‧ 盖部

602‧‧‧ Matching Department

603‧‧‧ external thread

604‧‧‧ sealing ring

Claims (10)

A quick cooling cup comprising a cup body and at least one heat pipe thermally connected to the cup body, the heat pipe comprising an evaporation section and a condensation section, the improvement being that the evaporation section is disposed on an outer surface of the cup body, the condensation The segment extends from the evaporation section in a direction away from the outer surface of the cup and is coupled to a heat dissipating component. The quick cooling cup according to claim 1, wherein the cup body comprises a bottom wall and a peripheral wall surrounding the bottom wall, wherein the peripheral wall is a cylindrical structure having upper and lower ends open, the bottom The wall is disposed and sealed to the lower end opening of the peripheral wall, and the evaporation section extends from the upper end opening of the cup to the lower end opening and then extends to the bottom wall. The quick cooling cup according to claim 2, wherein the condensation section is disposed vertically downward from a bottom wall of the cup body, and the condensation section is cylindrical. The quick cooling cup according to claim 2, wherein the evaporation section is vertically attached downward from the upper end opening of the cup body to the outer surface of the cup body, and the evaporation section is flat. The quick cooling cup according to the second aspect of the invention, wherein the heat dissipating component comprises a heat dissipating block, the heat dissipating block is disposed under the bottom wall of the cup body, and the heat dissipating block is provided with a joint portion. A condensation section of the heat pipe is inserted into the joint. The quick cooling cup according to claim 5, wherein the joint portion is a through hole corresponding to the number of the heat pipes. The quick cooling cup of claim 5, wherein the heat dissipating component further comprises a plurality of heat dissipating fins, the fins being divergently disposed around the heat dissipating block. The quick cooling cup according to claim 7, wherein the quick cooling cup further comprises a cup sleeve, the cup sleeve is sleeved with a cup body and a heat pipe, and the cup sleeve is provided with a plurality of vents. The quick cooling cup according to claim 8, wherein each of the fins extends from the heat dissipating block toward the vent of the cup sleeve. The quick cooling cup according to claim 8, wherein the cup sleeve comprises an upper end opening and a lower end opening, the upper end opening is provided with a flange, and the flange and the upper end of the cup An open port connection is provided, the vent opening being disposed adjacent to the lower end opening.