JP3239176U - Heat dissipation structure and skin rejuvenation device - Google Patents

Abstract

A heat dissipating structure and a skin rejuvenation device are provided that guarantee a heat dissipating effect, occupy a small space, and reduce costs. A heat dissipating structure includes a substrate (1), a heat conducting plate (2) provided on the substrate (1) to which a cooler (5) is attached, and a heat dissipating fin assembly (3) including a plurality of heat dissipating fins (32) provided on the heat conducting plate (2). and a radiating fin assembly 3 provided with a mounting groove 31 to which the lamp assembly 4 is mounted. The heat-conducting plate 2 dissipates the heat of the cooler 5 to avoid the temperature of the body-contacting part of the skin rejuvenation device from becoming too high and reduce the risk of burns to the user. The heat generated during operation of the lamp assembly 4 can be transferred to the radiating fin assembly 3, and the radiating fin assembly 3 can dissipate heat from the lamp assembly 4 to prevent the temperature of the lamp assembly 4 from becoming too high. The heat dissipation structure can dissipate heat from the two heat sources of the lamp assembly 4 and the cooler 5 at the same time. [Selection drawing] Fig. 1

Description

The present application relates to the technical field of electronic devices, and more particularly to heat dissipation structures and skin rejuvenation devices.

Photo-beautifying skin treatment technology, which has been developed based on laser technology, has made remarkable progress, from the first telangiectasia treatment, photo-hair removal, and photorejuvenation technology (IPL) using ultra-short pulse light to narrow-spectrum light technology (DPL). there is Generally, a whitening/skin rejuvenation device realizes hair removal and whitening/skin rejuvenation using the above technology. During the operation of the conventional whitening/skin rejuvenation device, the lamp assembly is energized to emit light and emit a large amount of heat, so the temperature of the contact area at the light outlet of the whitening/skin rejuvenation device rises rapidly, causing the user to There is a risk of burns.

The purpose of this utility model is to provide a heat dissipation structure and a skin rejuvenation device that solves the technical problem that the conventional whitening and skin rejuvenation devices tend to burn the user.

To solve the above problems, the embodiments of the present utility model provide the following technical solutions.

a substrate;
a thermally conductive plate provided on the substrate to which a cooler is attached;
A heat dissipating structure comprising: a heat dissipating fin assembly including a plurality of heat dissipating fins provided on the heat conducting plate, wherein the heat dissipating fin assembly is provided on the heat conducting plate and has a mounting groove for mounting a lamp assembly. .

Further, the heat conduction plate is a vapor chamber (VC), and the plurality of heat radiation fins are arranged side by side so as to be in close contact with the heat conduction plate.

Further, the heat-conducting plate comprises a first plate, a second plate, a heat-conducting medium and a heat-conducting body, wherein the first plate is attached to the second plate, and the first plate is sealed. formed between the second plates to form a chamber, wherein the heat conducting medium is provided within the sealed chamber, and the heat conductor is provided within the sealed chamber to form the first plate and the second plate; Adhere to the plate.

Further, the lamp assembly comprises a lamp holder, a lamp and a light reflecting cup, wherein the lamp holder is mounted on the heat conducting plate, one end of the heat conducting plate extends to protrude from the lamp holder, and the cooling A vessel is mounted on the heat conducting plate at a position protruding from the lamp holder, the light reflecting cup is provided in the lamp holder, the lamp is provided in the light reflecting cup, and the light reflecting cup and the lamp are Both are positioned within the mounting groove.

Further, the heat dissipation structure is provided between the lamp holder and the heat dissipating fin assembly, one end is in close contact with the heat dissipating fin assembly, and the other end is in close contact with the light reflector cup, which is a heat-conducting insulating material. Prepare more materials.

Further, an arc-shaped groove is provided at one end of the heat-dissipating fins facing the lamp assembly, and the mounting grooves are formed by the arc-shaped grooves of a plurality of heat-radiating fins.

Further, the lamp holder is provided with an arcuate mounting portion positioned within the mounting groove, a mounting chamber is provided within the arcuate mounting portion, and the light reflecting cup is mounted within the mounting chamber.

Further, the arc-shaped mounting portion is provided with a through groove, the heat-conducting material comprises a mounting portion and an arc-shaped heat-conducting portion connected to the mounting portion, the mounting portion is provided on the lamp holder, and the circular A protrusion is provided at one end of the arc-shaped heat-conducting part facing the light reflection cup, and the protrusion extends into the through groove to be in close contact with the light reflection cup.

Further, the light reflecting cup and the lamp holder are connected by snaps,
the mounting portion and the lamp holder are connected by screws, the mounting portion is provided with a mounting hole, and the lamp holder is provided with a screw hole;
The thermally conductive insulating material is thermally conductive silicone or aluminum nitride.

To solve the above technical problems, the embodiments of the present utility model further provide a skin rejuvenation device, adopting the following technical solutions.

A skin rejuvenation device comprising a case, a cooling driving part, a cooler, a cooling part, and a heat dissipation structure as described above, wherein the cooling driving part and the heat dissipation structure are provided in the case, and the cooling driving part is externally cooled. A skin rejuvenation device for driving a medium to blow onto the heat dissipation structure, wherein the cooler is provided on the heat dissipation structure, and the cooling part is provided on a case and connected to the cooler. .

Compared with the prior art, the embodiments of the present utility model mainly have the following beneficial effects.
The heat dissipation structure and skin rejuvenation device of the present utility model can be applied to the skin rejuvenation device to dissipate heat. The lamp assembly of the skin rejuvenation device emits light rays to achieve skin care such as hair removal, whitening, and skin rejuvenation. The cooler attached to the heat-conducting plate cools the skin-contacting part of the skin rejuvenation device, and can realize the cooling sensation of the body-contacting part of the skin rejuvenation device. The heat-conducting plate allows the cooler to dissipate heat to avoid overheating of the body-contacting portion of the skin rejuvenation device and reduce the risk of burns to the user. The lamp assembly is installed in the mounting groove of the heat radiating fin assembly, the heat generated during the operation of the lamp assembly can be transferred to the heat radiating fin assembly, and the heat radiating fin assembly dissipates the heat from the lamp assembly to prevent the lamp assembly from overheating. do. By driving the external cooling driving unit, the external cooling medium is blown onto the heat conducting plate and the heat radiating fin assembly, and the heat of the heat conducting plate and the heat radiating fin assembly is taken away by the cooling medium. Therefore, the heat dissipation structure can dissipate the two heat sources of the lamp assembly and the cooler at the same time, which ensures the heat dissipation effect and occupies less space, so that the structure of the skin rejuvenation device is more reasonable, Cost is reduced.

In order to explain the solution of the present utility model more clearly, the drawings used in the description of the embodiments are briefly described below, but of course, the drawings described below are merely some of the present utility model. They are examples and one of ordinary skill in the art can conceive of other drawings based on these drawings without creative effort.
1 is a structural schematic diagram of a heat dissipation structure in an embodiment of the present utility model; FIG. FIG. 3 is a structural schematic diagram of a heat conduction plate in an embodiment of the present utility model; FIG. 4 is a diagram schematically showing the connection relationship between the heat dissipation structure, the lamp assembly and the cooler in the embodiment of the present utility model; FIG. 4 is a diagram schematically showing the connection relationship between the lamp assembly and the heat-conducting material in the embodiment of the present utility model; FIG. 4 is a diagram schematically showing the connection relationship between the lamp and the light reflecting cup in the embodiment of the present utility model; FIG. 3 is a structural schematic diagram of a lamp assembly in an embodiment of the present utility model; FIG. 4 is a structural schematic diagram of a lamp holder in an embodiment of the present utility model; FIG. 3 is a structural schematic diagram of a thermally conductive material in an embodiment of the present utility model; 1 is a structural schematic diagram of a skin rejuvenation device in an embodiment of the present utility model; FIG. FIG. 4 is a diagram schematically showing the connection relationship between the cooling driving part, the lamp assembly and the heat dissipation structure in the embodiment of the present utility model;

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terms used in the description of the utility model are merely for describing specific embodiments and are not intended to limit the utility model. The terms "including", "having" and any variations thereof used in the specification, claims and description of the above drawings of this utility model are intended to cover the non-exclusive inclusion. do. The terms "first", "second", etc. in the specification of this utility model, the claims of the utility model registration, or the above drawings are for distinguishing different objects and for describing a specific order. is not.

"Example" as referred to herein means that the particular feature, structure or characteristic described by the example can be included in at least one example of the utility model. The appearances of such terms in various places in the specification do not necessarily refer to the same embodiment, nor are they necessarily independent or alternative embodiments to other embodiments. It is understood by those skilled in the art, either explicitly or implicitly, that the embodiments described herein may be combined with other embodiments.

In order to make the solution of the present utility model better understood by those skilled in the art, the following clearly and completely describes the technical solutions in the embodiments of the present utility model with reference to the relevant drawings.

As shown in FIGS. 1 and 3,
a substrate 1;
a heat conduction plate 2 provided on the substrate 1 and to which a cooler 5 is attached;
a heat dissipating fin assembly 3 including a plurality of heat dissipating fins 32 provided on the heat conducting plate 2, wherein the heat dissipating fin assembly 3 is provided on the heat conducting plate 2 and provided with mounting grooves 31 to which the lamp assemblies 4 are mounted; It is a heat dissipation structure.

The heat dissipation structure provided in the embodiments of the present utility model can be applied to the skin rejuvenation device to dissipate heat. The lamp assembly 4 of the skin rejuvenation device emits light rays to achieve skin care such as hair removal, whitening, and skin rejuvenation. The cooler 5 attached to the heat-conducting plate 2 cools the skin-contacting part of the skin-rejuvenation device, and can realize the cooling sensation of the skin-contacting part of the skin-rejuvenation device. The heat-conducting plate 2 allows the cooler 5 to dissipate heat, avoiding the temperature of the body-contacting part of the skin rejuvenation device from becoming too high, and reducing the risk of burns to the user. The lamp assembly 4 is installed in the mounting groove 31 of the radiating fin assembly 3 so that the heat generated during the operation of the lamp assembly 4 can be transmitted to the radiating fin assembly 3, and the radiating fin assembly 3 dissipates the heat from the lamp assembly 4. Avoid overheating. By driving the external cooling drive unit 7, the external cooling medium is sprayed onto the heat conducting plate 2 and the heat radiating fin assembly 3, and the heat of the heat conducting plate 2 and the heat radiating fin assembly 3 is taken away by the cooling medium. Therefore, the heat dissipation structure can dissipate the two heat sources of the lamp assembly 4 and the cooler 5 at the same time, which ensures the heat dissipation effect and occupies less space, which makes the structure of the skin rejuvenation device more reasonable. , the cost is reduced.

The heat conduction plate 2 is one of a vapor chamber (VC), a graphene heat dissipation film, a heat dissipation bracket, and a heat pipe.

In one embodiment, the heat conducting plate 2 is a vapor chamber (VC). The vapor chamber (VC) has better uniformity and stability than a heat pipe or a heatsink based on a metal substrate 1, and can make the temperature of the surface more uniform. Also, the use of a vapor chamber (VC) allows the heat source to be in direct contact with the vapor chamber (VC) to reduce thermal resistance.

The radiating fin assembly 3 includes a plurality of radiating fins 32 arranged in close contact with the heat conduction plate 2 . Alternatively, the heat radiating fins 32 can be cast iron heat radiating fins 32, steel heat radiating fins 32, or aluminum alloy heat radiating fins 32. Since heat is dissipated by countercurrent flow, it is understood that the larger the covered area, the higher the heat dissipating effect, and the plurality of heat dissipating fins 32 completely cover the output end of the cooling drive section 7 .

Alternatively, the heat dissipating fins 32 and the heat conducting plate 2 in the heat dissipating fin assembly 3 are integrally formed, so that the heat dissipating fin assembly 3 and the heat conducting plate 2 are integrally connected, and under the action of heat transfer, the cooling driving part As the external cooling medium is drawn into the skin rejuvenation device by 7, the heat of the radiating fins 32 and the heat-conducting plate 2 is immediately transferred by the external cooling medium to achieve rapid cooling.

As shown in FIG. 2, the heat conducting plate 2 comprises a first plate 21, a second plate 22, a heat conducting medium 23 and a heat conductor 24, wherein the first plate 21 is connected to the second plate 22, the first plate 21 is provided between the second plates 22 to form a sealed chamber, the heat conducting medium 23 is provided in the sealed chamber, the heat conductor 24 is provided in the sealed chamber and is in close contact with the first plate 21 and the second plate 22 .

Alternatively, the heat conductor 24 may be a copper mesh heat-conducting mesh having a capillary structure, which increases the contact area between the heat-conducting medium 23 and the first plate 21 and the second plate 22 to achieve uniformity. to increase the heat conduction efficiency of the heat conducting plate 2. Optionally, said heat transfer medium 23 is a coolant, preferably an aqueous coolant. By sufficiently contacting the heat-conducting mesh with the heat-conducting medium 23, the contact area between the heat-conducting medium 23 and the first plate 21, the second plate 22, and the heat-conducting net is increased, and the heat-conducting medium 23 is used for the cooling. The heat absorbed by the heat-conducting plate 2 from the vessel 5 can be quickly absorbed, and the heat can be quickly conducted to the heat-dissipating fin assembly 3, so that the heat-dissipating fin assembly 3 can dissipate the heat. can.

3 to 8, the lamp assembly 4 comprises a lamp holder 41, a lamp 42 and a light reflecting cup 43, the lamp holder 41 is installed on the heat conducting plate 2, and one end of the heat conducting plate 2 is extends so as to protrude from the lamp holder 41, the cooling part 9 is attached to the heat conductive plate 2 at a position protruding from the lamp holder 41, and the light reflecting cup 43 is provided on the lamp holder 41. , the lamp 42 is installed in the light reflecting cup 43 , and the light reflecting cup 43 and the lamp 42 are both located in the mounting groove 31 ;

The heat-dissipating structure further includes a heat-conducting material 34 disposed between the lamp holder 41 and the heat-dissipating fin assembly 3 , one end of which is in close contact with the heat-dissipating fin assembly 3 and the other end of which is in close contact with the light reflecting cup 43 . Prepare.

In one embodiment, the thermally conductive material 34 is made of a thermally conductive insulating material, and the thermally conductive material 34 is preferably thermally conductive silicone or aluminum nitride, but may be other thermally conductive insulating materials. The heat-conducting gel can conduct the heat of the light reflecting cup 43 during operation of the lamp assembly 4 to the heat dissipating fin assembly 3 . Blowing onto the conduction assembly, it can carry away the heat of two heat sources, the cooler 5 and the lamp assembly 4 .

In one embodiment, one end of the heat radiating fins 32 facing the lamp assembly 4 is provided with an arcuate groove 33 , and the mounting grooves 31 are formed by the arcuate grooves 33 of a plurality of heat radiating fins 32 .

In one embodiment, the lamp holder 41 is provided with an arc-shaped mounting portion 411 located in the mounting groove 31, a mounting chamber is provided in the arc-shaped mounting portion 411, and the light reflecting cup 43 is mounted on the mounting chamber. mounted inside.

In one embodiment, the arc-shaped mounting part 411 is provided with a through groove 412 , the heat-conducting material 34 comprises a mounting part 341 and an arc-shaped heat-conducting part 342 connected to the mounting part 341 , and the mounting part 341 is provided in the lamp holder 41, and a protrusion 344 is provided at one end of the arc-shaped heat conduction part 342 toward the light reflection cup 43, and the protrusion 344 extends into the through groove 412 to allow the light It adheres to the reflecting cup 43 .

In one embodiment, the light reflector cup 43 and the lamp holder 41 are snap connected.
The mounting portion 341 and the lamp holder 41 are connected by screws, the mounting portion 341 is provided with a mounting hole 343 , and the lamp holder 41 is provided with a screw hole 413 .

The heat dissipation structure provided in the embodiments of the present utility model can be applied to the skin rejuvenation device to dissipate heat. The lamp assembly 4 of the skin rejuvenation device emits light rays to achieve skin care such as hair removal, whitening, and skin rejuvenation. The cooler 5 attached to the heat-conducting plate 2 cools the skin-contacting part of the skin-rejuvenation device, and can realize the cooling sensation of the skin-contacting part of the skin-rejuvenation device. The heat-conducting plate 2 allows the cooler 5 to dissipate heat, avoiding the temperature of the body-contacting part of the skin rejuvenation device from becoming too high, and reducing the risk of burns to the user. The light reflecting cup 43 of the lamp assembly 4 is connected to the radiating fin assembly 3 through the heat-conducting material 34 , so that the heat generated during the operation of the lamp assembly 4 can be transferred to the radiating fin assembly 3 . To dissipate heat and avoid the temperature of the lamp assembly 4 becoming too high. By driving the cooling drive unit 7, the external cooling medium is sprayed onto the heat conducting plate 2 and the heat radiating fin assembly 3, and the heat of the heat conducting plate 2 and the heat radiating fin assembly 3 is taken away by the cooling medium. Therefore, the heat dissipation structure can dissipate the two heat sources of the lamp assembly 4 and the cooler 5 at the same time, which ensures the heat dissipation effect and occupies less space, which makes the structure of the skin rejuvenation device more reasonable. , the cost is reduced.

To solve the above technical problems, the embodiments of the present utility model further provide a skin rejuvenation device, adopting the following technical solutions.

As shown in FIGS. 9 and 10, a skin rejuvenation device comprising a case 6, a cooling drive unit 7, a cooler 5, a cooling unit 9, and a heat dissipation structure as described above, wherein the cooling drive unit 7 and the heat dissipation structure is provided in the case 6, the cooling driving part 7 is for driving the external cooling medium to blow the heat dissipation structure, the cooler 5 is provided in the heat dissipation structure, the cooling part A skin rejuvenation device 9 is provided in the case 6 and connected to the cooler 5 .

In this embodiment, the skin rejuvenation device is a DPL skin rejuvenation device. Narrow spectrum light (DPL) is a new type of photorejuvenation technology with a spectral range of 500-600 nm or 550-650 nm. In contrast to conventional photorejuvenation technology (IPL), narrow-spectrum light technology can excite narrow-spectrum pulsed light selected in the 100 nm wavelength range. This wavelength range contains both the absorption peaks of melanin, oxygen and hemoglobin, allowing effective therapeutic energy to be precisely focused to quickly and efficiently resolve facial blemishes and telangiectasia (blush) problems can do. Skin rejuvenation using DPL narrow-spectrum light is clearly more effective than photorejuvenation, and the treatment period is greatly shortened.

In one embodiment, the cooling medium may be air, and the cooling driver 7 may be a fan such as an axial fan, a centrifugal fan or a mixed fan. Said cooling drive 7 is preferably an axial fan, and when the axial fan operates, the blades move the air to flow in the same direction as the axis.

Said cooling medium may be for example water or other cooling medium such as cooling liquid, which is sucked and delivered by water pumps and water pipes.

Of course, the embodiments described above are only some embodiments of the present utility model, but not all embodiments. Although the drawings show preferred embodiments of the utility model, they are not intended to limit the patent scope of the utility model. The utility model can be embodied in many different forms, rather these examples are provided for the purpose of providing a more thorough and thorough understanding of the disclosure of the utility model. Although the present utility model has been described in detail with reference to the above embodiments, those skilled in the art can still modify the technical solutions described in each of the above specific embodiments, or some technical features thereof. Equivalent permutations can be made to Equivalent structures made using the contents of the specification and drawings of this utility model, or direct or indirect applications in other related technical fields, are all included within the scope of the claims of this utility model for the same reason. be

REFERENCE SIGNS LIST 1 substrate 2 heat conduction plate 21 first plate 22 second plate 23 heat conduction medium 24 heat conductor 3 heat dissipation fin assembly 31 mounting groove 32 heat dissipation fin 33 arc groove 34 heat conduction material 341 mounting portion 342 arc heat conduction Portion 343 Mounting hole 344 Protruding portion 4 Lamp assembly 41 Lamp holder 411 Circular mounting portion 412 Through groove 413 Screw hole 42 Lamp 43 Light reflecting cup 5 Cooler 6 Case 7 Cooling driver 8 Blow-out port 9 Cooling unit

Claims (10)

a substrate;
a thermally conductive plate provided on the substrate to which a cooler is attached;
A heat dissipating fin assembly including a plurality of heat dissipating fins provided on the heat conducting plate, wherein the heat dissipating fin assembly is provided on the heat conducting plate and has a mounting groove for mounting the lamp assembly. , heat dissipation structure. The heat dissipating structure according to claim 1, wherein said heat conducting plate is a vapor chamber (VC), and a plurality of said heat dissipating fins are arranged side by side so as to be in close contact with said heat conducting plate. The heat-conducting plate comprises a first plate, a second plate, a heat-conducting medium and a heat-conducting body, wherein the first plate is attached to the second plate, and the first plate defines a sealed chamber. between the second plate so as to form, the heat conducting medium is provided within the sealed chamber, and the heat conductor is provided within the sealed chamber to form the first plate and the second plate; The heat dissipation structure according to claim 1, characterized in that it is in close contact with the body. The lamp assembly comprises a lamp holder, a lamp and a light reflecting cup, wherein the lamp holder is mounted on the heat conducting plate, one end of the heat conducting plate protrudes from the lamp holder, and the cooler comprises: The heat-conducting plate is mounted at a position protruding from the lamp holder, the light reflecting cup is provided in the lamp holder, the lamp is provided in the light reflecting cup, and the light reflecting cup and the lamp are both attached to the lamp. The heat dissipation structure according to claim 3, wherein the heat dissipation structure is located in the mounting groove. The lamp further comprises a thermally conductive material, which is a thermally conductive insulating material, provided between the lamp holder and the heat radiating fin assembly, one end of which is in close contact with the heat radiating fin assembly, and the other end of which is in close contact with the light reflecting cup. The heat dissipation structure according to claim 4, wherein 5. The heat dissipation structure as claimed in claim 4, wherein one end of the heat dissipation fins facing the lamp assembly is provided with an arcuate groove, and the mounting grooves are formed by the arcuate grooves of a plurality of heat dissipation fins. wherein the lamp holder is provided with an arc-shaped mounting portion located in the mounting groove, a mounting chamber is provided in the arc-shaped mounting portion, and the light reflecting cup is mounted in the mounting chamber; The heat dissipation structure according to claim 5. The arc-shaped mounting part is provided with a through groove, the heat-conducting material comprises a mounting part and an arc-shaped heat-conducting part connected to the mounting part, the mounting part is provided on the lamp holder, and the arc-shaped heat The heat sink according to claim 7, characterized in that a protrusion is provided at one end of the conductive part facing the light reflection cup, and the protrusion extends into the through groove to be in close contact with the light reflection cup. structure. the light reflecting cup and the lamp holder are connected by snaps,
the mounting portion and the lamp holder are connected by screws, the mounting portion is provided with a mounting hole, and the lamp holder is provided with a screw hole;
The heat dissipation structure according to claim 7, characterized in that said thermally conductive insulating material is thermally conductive silicone or aluminum nitride. A skin rejuvenation device comprising a case, a cooling driving section, a cooler, a cooling section, and the heat dissipation structure according to any one of claims 1 to 9, wherein the cooling driving section and the heat dissipation structure are provided in the case. wherein the cooling driving part is for driving an external cooling medium to spray the heat dissipation structure, the cooler is provided in the heat dissipation structure, the cooling cap part is provided in the case, and the cooler is A skin rejuvenation device, characterized in that it is connected to a

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