RU2846031C2 - Device with an inductance coil used in a smoking set with uniform heating by magnetic particles, and a method for manufacturing same - Google Patents

Abstract

FIELD: smoking accessories.

SUBSTANCE: device with an induction coil, used in a smoking set with uniform heating by magnetic particles, and a method of manufacturing same, wherein the device comprises a device housing inside of which there is a hole, wherein the device housing is two-layered, and between the inner housing and the outer housing a vacuum layer is formed in which induction coil (1), heat-insulating material layer (2) and electromagnetic radiation shielding coating layer (3) are located; induction coil (1) is wound on the outer side wall of inner housing (4), and heat-insulating material layer (2) is wrapped around the periphery of induction coil (1); layer (3) of the coating which shields from electromagnetic radiation lies on the inner side wall of outer housing (5), and the vacuum gap between layer (3) of the coating which shields from electromagnetic radiation and layer (2) of heat-insulating material forms a vacuum heat-insulating layer.

EFFECT: device with an inductance coil has both electromagnetic shielding and heat-insulating characteristics, achieves a good shielding effect from radiation of electromagnetic waves, significantly insulates heat of the induction coil itself and achieves reduction of losses for eddy currents of the induction coil and reduction of temperature of the smoking set housing.

8 cl, 1 dwg

Description

Field of technology

The invention relates to the field of technologies for heating tobacco products in smoking sets and, in particular, to a device with an induction coil, applicable in a smoking set with uniform heating by magnetic particles, and a method for its manufacture.

Prior art

The electromagnetic induction heating technology is applied to a smoking kit with uniform heating by magnetic particles, in which an alternating electromagnetic field is generated by an induction coil, and the ferromagnetic element inserted into the cigarette to be heated is placed in the alternating electromagnetic field so that it generates and releases heat to heat the substance in the cigarette for puffing. In the electromagnetic induction heating process, it is necessary for the electromagnetic shielding and heat insulation device to be designed because the induction coil generates electromagnetic wave radiation and self-heats. In most cases, the electromagnetic shielding and heat insulation device are composed of separate modules for the corresponding process. Although they can meet certain design requirements, there are problems such as poor electromagnetic shielding effect, low heat insulation performance, etc.

Disclosure of invention

The purpose of the invention is to overcome the disadvantages of the prior art, and a device with an induction coil, applicable in a smoking set with uniform heating by magnetic particles, and a method for its manufacture for the innovative development of a device with an induction coil, having both electromagnetic shielding and heat-insulating characteristics, by integrating electromagnetic shielding and heat-insulating characteristics, thereby achieving a good shielding effect from the radiation of electromagnetic waves, significantly insulating the heat of the induction coil itself, and achieving a reduction in eddy current losses of the induction coil and a reduction in the temperature of the housing of the smoking device.

The invention is implemented through the following technical solutions.

A device with an induction coil, applicable in a smoking set with uniform heating by magnetic particles, comprises a device housing, inside which an opening is made, wherein the device housing is made in two layers, and between the inner housing and the outer housing a vacuum layer is formed, in which an induction coil, a layer of heat-insulating material and a layer of coating shielding from electromagnetic radiation are located; wherein the induction coil is wound on the outer side wall of the inner housing, and the layer of heat-insulating material is wrapped around the outer periphery of the induction coil; the layer of coating shielding from electromagnetic radiation is located on the inner side wall of the outer housing, and the vacuum gap between the layer of coating shielding from electromagnetic radiation and the layer of heat-insulating material forms a vacuum heat-insulating layer.

As a preferred solution for the above-mentioned device, at two ends of the induction coil, respectively, there are end conductive contacts, and said two end conductive contacts are led out from the external device.

As a preferred solution for the above-mentioned device, at least one conductive contact of the middle section is provided on the middle section of the induction coil, and each conductive contact of the middle section is led out from the outer housing.

As a preferred solution for the above-mentioned device, the material of the outer casing is one of the following: a metallic material shielding against electromagnetic radiation, a surface-conducting material shielding against electromagnetic radiation, or a filling composite material shielding against electromagnetic radiation.

As a preferred solution for the above device, the inner casing material is insulating material.

As a preferred solution for the above-mentioned device, the electromagnetic radiation shielding coating layer is formed by coating the inner side wall of the outer housing with a conductive coating.

As a preferred solution for the above-mentioned device, the heat-insulating material layer is composed of a main body and a galvanic layer, wherein the main body is formed from one or a mixture of several materials such as glass fiber, aerogel, foam and fibrous fabric, and the galvanic layer is formed by electroplating a metal and a conductive material on the surface of the main body.

According to the invention, a method for manufacturing a device with an induction coil, applicable in a smoking set with uniform heating by magnetic particles, is also proposed, where the device with an induction coil is the above-mentioned device with an induction coil, and the method for manufacturing the device with an induction coil is carried out sequentially in accordance with the following steps:

Step 1: Prepare a thermal insulation sheet using a thermal insulation material, wrap the thermal insulation sheet around the outer periphery of the induction coil, and form a seal to obtain a ring-shaped layer of thermal insulation material;

Step 2: Grind the insulation material into powder, add the adhesive and water-based additives, and mix and stir them to obtain an insulation slurry, inject the insulation slurry into the inner casing mold, and perform high-temperature sintering to obtain the inner casing;

Step 3: Prepare the outer casing using electromagnetic shielding material so that the outer casing performs the electromagnetic shielding function;

Step 4: Coating the inner side wall of the outer casing with an electromagnetic radiation shielding material to form an electromagnetic radiation shielding coating layer;

Step 5: putting the induction coil on the outer periphery of the inner casing, and then putting the outer casing on the outer periphery of the heat-insulating material layer, wherein the electromagnetic radiation shielding coating layer on the inner layer of the outer casing is not in contact with the heat-insulating material layer, then sealing the upper and lower ends of the inner casing and the outer casing to form a whole and evacuated annular cavity between the inner casing and the outer casing, so as to obtain a vacuum layer between the inner casing and the outer casing.

As a preferred solution for the above-mentioned manufacturing method, at the two ends of the induction coil, respectively, there are end conductive contacts, and at least one conductive contact of the middle section is provided on the middle section of the induction coil, wherein the end conductive contact and the conductive contact of the middle section are respectively led outward from the reserved output openings on the outer housing, and the gap between the output opening of the outer housing and the corresponding conductive contact is insulated and sealed.

The invention has the following advantages over the known state of the art:

1. The induction coil device applicable to a smoking kit with uniform heating by magnetic particles proposed according to the invention has a heat-insulating material layer and an electromagnetic radiation shielding coating layer effectively combined with each other, which allows the device to provide both electromagnetic shielding and thermal insulation, significantly improving the effect of electromagnetic shielding and thermal insulation of the induction coil device. In addition, a two-layer housing structure is used in the device body, and in addition to the heat-insulating material layer, the vacuum gap between the electromagnetic radiation shielding coating layer and the heat-insulating material layer also forms a vacuum heat-insulating layer, which further enhances the heat-insulating characteristics and effectively prevents heat loss and significantly improves the heating efficiency of the cigarette.

2. The method for manufacturing a device with an induction coil applicable in a smoking set with uniform heating by magnetic particles proposed according to the invention is simple and convenient to operate, is effective and inexpensive; at the same time, the product yield is high and the loss is small. The device with an induction coil manufactured in accordance with this method has the following advantages:

Firstly, the manufactured induction coil device adopts an integrated structure, which combines the functions of thermal insulation and electromagnetic shielding. At the same time, a dual form of electromagnetic shielding is adopted, which greatly improves the efficiency of electromagnetic shielding;

secondly, the vacuum layer formed in the manufactured device with an induction coil effectively reduces energy loss caused by the generation of its own heat by the induction coil, and significantly prevents heat from being dissipated outside the device body, thereby reducing the temperature on the surface of the smoking device body with uniform heating by magnetic particles;

again, the finished device with an induction coil has a function for adjusting the inductance value. Due to the presence of several conductive contacts that are brought out, it is possible to conveniently and selectively connect the electromagnetic oscillatory circuit, thereby selecting the design of the heating smoking device with different frequencies of electromagnetic oscillations.

Brief description of the drawings

Fig. 1 shows the invention in a state of use, a sectional view.

Reference positions in the drawing: 1 - induction coil, 2 - heat-insulating material layer, 3 - electromagnetic radiation shielding coating layer, 4 - inner casing, 5 - outer casing, 6 - vacuum heat-insulating layer, 7 - end conductive contact, 8 - conductive contact of the middle section, 9 - cigarette, 10 - inductive heating element, 11 - base, 12 - mounting protrusion.

Embodiments of the invention

The following provides a detailed explanation of embodiments of the invention that are realized based on the technical solution according to the invention, detailed implementations and specific operating procedures, but the scope of protection of the invention is not limited to the embodiments given below.

With reference to Fig. 1, in an embodiment, a device with an induction coil is proposed, applicable in a smoking kit with uniform heating by magnetic particles, which comprises a device housing, inside which an opening is made, wherein the device housing is made in two layers, and a vacuum layer is formed between the inner housing and the outer housing; an induction coil 1, a layer 2 of heat-insulating material and a layer 3 of a coating shielding from electromagnetic radiation are made in the vacuum layer; the induction coil 1 is wound on the outer side wall of the inner housing 4, and a layer 2 of heat-insulating material is wrapped around the outer periphery of the induction coil 1; a layer 3 of a coating shielding from electromagnetic radiation is located on the inner side wall of the outer housing 5, and the vacuum gap between layer 3 of the coating shielding from electromagnetic radiation and layer 2 of heat-insulating material forms a vacuum heat-insulating layer 6.

At the two ends of the induction coil 1, there are respectively end conductive contacts 7, and two end conductive contacts 7 are brought out from the outer housing 5. At the middle section of the induction coil 1, there is at least one conductive contact 8 of the middle section, and each conductive contact 8 of the middle section is brought out from the outer housing 5. Any two different conductive contacts can be selected in accordance with the requirements for connection to the electromagnetic oscillatory circuit, so that in accordance with the requirements, different turns of the coil can be selected to form different inductance values and to generate alternating current signals with different resonant frequencies.

The wire diameter, winding distance, number of turns and inductance value of induction coil 1 satisfy the following relationship: 0.5 mm < wire diameter < 2.5 mm, 0.05 mm < winding distance < 0.5 mm, 6 < number of turns < 14, 0.1 μH < inductance value < 35 μH.

The material of the outer case 5 is one of the following: a metal material shielding against electromagnetic radiation, a surface-conducting material shielding against electromagnetic radiation, or a filling composite material shielding against electromagnetic radiation. The outer case 5 is made of a material shielding against electromagnetic radiation, which can act as a rigid support for the device case, and can also work together with the coating layer 3 shielding against electromagnetic radiation on its inner side, providing a double electromagnetic shielding effect.

The material of the inner casing 4 is an insulating material which is made of either one or a mixture of any two of the following materials: glass, ceramics and plastic. Using the insulating material as the material of the inner casing 4 makes it possible to insulate the induction coil 1 and prevent damage and leakage of the insulating wrapping layer of the induction coil 1, eliminating the safety hazard.

Layer 3 of the coating shielding against electromagnetic radiation is formed by coating the inner side wall of the outer housing 5 with a conductive coating.

Layer 2 of the heat-insulating material consists of a main body and a galvanic layer. The main body is formed of fiberglass and/or aerogel and/or foam and/or fibrous fabric, and the galvanic layer is formed by galvanic coating of metal and conductive material on the surface of the main body.

The embodiment also discloses a method for manufacturing a device with an induction coil, applicable in a smoking kit with uniform heating by magnetic particles, wherein the method for manufacturing a device with an induction coil is carried out sequentially in accordance with the following steps:

step 1: producing a thermal insulation sheet using a thermal insulation material (the specific process is as follows: selecting one or a mixture of several of the following materials: glass fiber, aerogel, foam plastic and fibrous fabric, to produce a thermal insulation gel by an organic-inorganic hybrid method, then freezing and drying the thermal insulation gel to freeze the liquid in the thermal insulation gel hole, and then sublimating it under vacuum to obtain a main body of a thermal insulation sheet; further, according to requirements, metallic and conductive materials may be further applied to the surface of the main body of the thermal insulation sheet to form a galvanic layer of the thermal insulation sheet. The main body and the galvanic layer together form a thermal insulation sheet); wrapping the thermal insulation sheet around the outer periphery of the induction coil 1 and forming a seal to obtain an annular layer 2 of a thermal insulation material;

step 2: grinding the insulating material into powder, adding adhesive and water-based additives, and mixing and stirring them to obtain an insulating slurry, injecting the insulating slurry into a mold for the inner casing 4, and performing high-temperature sintering to obtain the inner casing 4 (the specific process is as follows: selecting either one or a mixture of any two materials of glass, ceramics and plastic to grind into nano-sized fine powder, adding adhesive and water-based additive, mixing and stirring, and then injecting into the mold for the inner casing 4 for molding, and performing high-temperature sintering to obtain the inner casing 4);

Step 3: prepare the outer casing 5 using an electromagnetic shielding material so that the outer casing 5 performs an electromagnetic shielding function;

step 4: coating the inner side wall of the outer case 5 with an electromagnetic radiation shielding material to form an electromagnetic radiation shielding coating layer 3; (the specific process is as follows: coating the inner side wall of the outer case 5 with a conductive coating by spraying, chemical electroplating, deposition or screen printing process to form an electromagnetic radiation shielding coating layer 3 with a thickness of 25-300 μm);

Step 5: putting the induction coil 1 on the outer periphery of the inner casing 4, and then putting the outer casing 5 on the outer periphery of the layer 2 of the heat-insulating material, where the layer 3 of the coating shielding against electromagnetic radiation on the inner layer of the outer casing 5 is not in contact with the layer 2 of the heat-insulating material, then sealing the upper and lower ends of the inner casing 4 and the outer casing 5 to form a whole and evacuated annular cavity between the inner casing 4 and the outer casing 5, in order to obtain a vacuum layer between the inner casing and the outer casing.

The end conductive contacts 7 are respectively provided at the two ends of the induction coil 1, and at least one conductive contact 8 of the middle section is provided on the middle section of the induction coil 1. The end conductive contact 7 and the conductive contact 8 of the middle section are respectively provided from the reserved output openings on the outer casing 5, and the gap between the output opening of the outer casing 5 and the corresponding conductive contact is insulated and sealed.

At stage 3 of the manufacturing method described above, one of three materials shielding against electromagnetic radiation can be used as the material of the outer casing 5.

If the outer casing 5 is made of a metal material shielding against electromagnetic radiation, a ferromagnetic material or a metal material with good conductivity can be selected. Ferromagnetic materials include iron, cobalt, nickel, etc., and metal materials with good conductivity include silver, copper, aluminum, etc. The manufacturing method is as follows: the outer casing 5 is manufactured by mixing and grinding the metal material shielding against electromagnetic radiation into a nano-sized fine powder, uniformly mixing the powder, and then melting and pouring the fine powder into a mold for the outer casing for casting and annealing.

If the outer casing 5 is made of a surface-conducting material that shields against electromagnetic radiation, then the manufacturing method consists in that the outer casing 5 is manufactured by pre-fabricating the body of the outer casing of the device using any material and applying a thin layer of conductive coating to the surface of the body of the outer casing by means of one or more of the following processes: spraying, chemical electroplating, deposition, screen printing.

If the outer casing 5 is made of a filling composite material shielding against electromagnetic radiation, the manufacturing method is as follows: using a polymer resin as the main body, adding a certain amount of a conductive filler to the main body, the outer casing 5 is obtained by melt mixing, solution mixing, in-situ polymerization and co-precipitation methods.

The polymer resin material provides processing and molding performance and a certain degree of thermal insulation for the outer casing 5. The polymer materials include one or more synthetic products of polyethylene (PE), polyvinyl chloride (PVC), polystyrene (PS), polypropylene (PP), ABS plastic, polycarbonate (PC), nylon, polyetheretherketone (PEEK), and polyethersulfone (PES).

Conductive fillers include one or a mixture of carbon-based, metal-based, composite and polymer-based fillers. Carbon-based conductive fillers mainly include carbon black, graphene, carbon nanotubes and carbon fiber. Metal-based conductive fillers mainly include silver, copper, nickel and aluminum or their alloy. Composite-based conductive fillers mainly include one or a mixture of the following materials: silver-plated glass microspheres, nickel-plated graphene, nickel-plated carbon fiber, cobalt-coated graphene and cobalt-coated carbon fiber. Polymer-based conductive fillers mainly include one or a mixture of the following materials: polyaniline, polypyrrole and polythiophene.

When used, the device with an induction coil interacting with the inductive heating element 10 forms a smoking set with uniform heating by magnetic particles. The base 11 of the inductive heating element 10 is placed on the tabletop, the device with an induction coil is placed on the base 11 of the inductive heating element 10, and the opening is aligned and limited by the mounting protrusion 12 on the base 11, wherein the lower part of the opening in the device body can be closed by the base 11 of the inductive heating element 10. When heating, the cigarette 9 is inserted downwards from the upper part of the opening in the device body until the inductive heating element 10 is inserted into the inner part of the cigarette 9. For external connection of the electromagnetic oscillatory circuit, two conductive contacts are selected. The induction coil 1 is supplied with voltage to generate an electromagnetic field, and the inductive heating element 10 cuts off the alternating electromagnetic field to generate heat, as a result of which the cigarette 9 is sufficiently heated. The outer case 5 on the side wall of the device with the induction coil and the electromagnetic radiation shielding coating layer 3 on the inner side of the outer case 5 can suppress the leakage of the electromagnetic field generated by the induction coil 1 by half. The heat-insulating material layer 2 and the vacuum heat-insulating interlayer 6 can provide double heat-insulating performance, increasing the heating efficiency.

The foregoing represents only preferred embodiments of the invention and is not intended to limit the invention. Any modifications, equivalent replacements, improvements, etc., made in accordance with the essence and principles of the invention, shall be included in the scope of protection of the invention.

Claims (14)

1. A device with an induction coil used in a smoking set with uniform heating by magnetic particles, comprising a device housing, inside which an opening is made, wherein the device housing has a two-layer structure and between the inner housing (4) and the outer housing (5) a vacuum layer is formed, in which an induction coil (1), a layer (2) of heat-insulating material and a layer (3) of a coating shielding from electromagnetic radiation are located; wherein the induction coil (1) is wound on the outer side wall of the inner housing (4), and the layer (2) of heat-insulating material is wrapped around the outer periphery of the induction coil (1); the layer (3) of the coating shielding from electromagnetic radiation is located on the inner side wall of the outer housing (5), and the vacuum gap between the layer (3) of the coating shielding from electromagnetic radiation and the layer (2) of heat-insulating material forms a vacuum heat-insulating layer (6). 2. A device with an induction coil used in a smoking set with uniform heating by magnetic particles, according to paragraph 1, in which at the two ends of the induction coil (1) there are respectively two end conductive contacts (7) and the said two end conductive contacts (7) are led out of the outer casing (5). 3. A device with an induction coil used in a smoking set with uniform heating by magnetic particles, according to claim 2, in which the middle section of the induction coil (1) has at least one conductive contact (8) of the middle section and each conductive contact (8) of the middle section is led out of the outer casing (5). 4. A device with an induction coil used in a smoking set with uniform heating by magnetic particles, according to claim 1, in which the material of the outer casing is one of the following: a metallic material that shields from electromagnetic radiation, a surface-conducting material that shields from electromagnetic radiation, or a filling composite material that shields from electromagnetic radiation. 5. A device with an induction coil used in a smoking device with uniform heating by magnetic particles, according to claim 1, in which the material of the inner casing (4) is an insulating material. 6. A device with an induction coil used in a smoking set with uniform heating by magnetic particles, according to claim 1, in which the layer (3) of the coating shielding from electromagnetic radiation is formed by applying a conductive coating to the inner side wall of the outer housing (5). 7. A device with an induction coil used in a smoking set with uniform heating by magnetic particles, according to claim 1, in which the layer (2) of heat-insulating material consists of a main body and a galvanic layer, wherein the main body is formed from one or a mixture of several materials, such as fiberglass, aerogel, foam and fibrous fabric, and the galvanic layer is formed by a galvanic coating of metal and a conductive material on the surface of the main body. 8. A method for manufacturing a device with an induction coil used in a smoking set with uniform heating by magnetic particles, in which the device with an induction coil is a device with an induction coil according to item 1, and the method for manufacturing the device with an induction coil is carried out in accordance with the following steps: Step 1: preparing a heat-insulating sheet using a heat-insulating material, wrapping the heat-insulating sheet around the outer periphery of the induction coil (1), and forming a seal to form an annular layer (2) of the heat-insulating material; Step 2: Grinding the insulating material into powder, adding the adhesive and water-based additives, mixing and stirring them to obtain an insulating slurry, injecting the insulating slurry into the inner casing mold (4), and performing high-temperature sintering to obtain the inner casing (4); Step 3: Prepare the outer casing (5) using an electromagnetic shielding material so that the outer casing (5) performs the electromagnetic shielding function; Step 4: coating the inner side wall of the outer casing (5) with an electromagnetic radiation shielding material to form an electromagnetic radiation shielding coating layer (3); Step 5: putting the induction coil (1) on the outer periphery of the inner casing (4), and then putting the outer casing (5) on the outer periphery of the layer (2) of the heat-insulating material, where the layer (3) of the coating shielding against electromagnetic radiation on the inner layer of the outer casing (5) is not in contact with the layer (2) of the heat-insulating material, then sealing the upper and lower ends of the inner casing and the outer casing (5) to form a whole and evacuated annular cavity between the inner casing and the outer casing (5), so as to obtain a vacuum layer between the inner casing and the outer casing (5). 9. A method for manufacturing a device with an induction coil used in a smoking set with uniform heating by magnetic particles, according to claim 8, in which at the two ends of the induction coil, respectively, end conductive contacts (7) are made and at least one conductive contact (8) of the middle section is made on the middle section of the induction coil (1), wherein the end conductive contact (7) and the conductive contact (8) of the middle section are respectively led outward from reserved output openings on the outer casing (5), and the gap between the output opening of the outer casing (5) and the corresponding conductive contact is insulated and sealed.