KR101603579B1 - Heat sink assembled Apparatus for cooling adipolysis - Google Patents

Abstract

The present invention relates to a heat sink unit-integrated apparatus for cooling adipolysis, and more particularly, relates to a heat sink unit-integrated apparatus for cooling adipolysis including: a suction unit which sucks a subject into a receiving space; a vacuum suction unit which generates a vacuum pressure in the receiving space to adsorb a target region onto an inner wall surface of the receiving space of the suction unit; a cooling unit including a cooling element mounted on both sides of an inner wall of the suction unit facing each other to cool the target region adsorbed onto the inner side of the receiving space of the suction unit; a heat sink unit including a heat exchange body which is closely adhered to the outer surface of the cooling element arranged on both sides of the suction unit to absorb heat radiated from the cooling element, a heat exchange pipe one side of which is connected to the heat exchange body, other side of which is formed to be extended in an upper direction of the heat exchange body, and in which a heat transfer medium is moved, a heat sink including a plurality of radiation fins connected in the length direction of the other side of the heat exchange pipe to emit heat inside the heat exchange pipe to the outside, and a radiation fan which is installed on the bottom of the heat sink to emit air in the upper direction from the bottom of the radiation fins; and a top case including a louver formed on upper side, where the radiation fins are installed and the heat sink is stored by being combined to the upper side of the suction unit, in a predetermined length. The heat sink unit-integrated apparatus for cooling adipolysis according to the present invention has effects that cooling efficiency of the apparatus is increased by integrally combining a radiation unit for emitting heat generated from a thermoelectric element to the outside on the top of the suction unit, and that the apparatus can be simply used at any places by miniaturizing the apparatus and enabling the apparatus to be carried conveniently.

Description

TECHNICAL FIELD [0001] The present invention relates to a heat sink assembled Apparatus for cooling adipolysis,

The present invention relates to a heat dissipating unit-integrated cooling fat decomposition apparatus, and more particularly, to a heat dissipating unit-integrated cooling fat decomposition apparatus which integrates a heat dissipating unit for dissipating heat generated in a thermoelectric element in a cooling fat- And a heat dissipating unit integral type cooling fat decomposition apparatus which can be easily used.

As the quality of life has improved due to recent economic development, obesity is increasing due to excessive nutrition and lack of exercise, and also interest in diet is increasing. Various treatment techniques for the treatment of obesity in modern people are being developed.

For example, liposuction has been proposed to remove excess fat such as abdomen and thighs. However, since this method removes fat by inhaling a portion of the area through surgery, . In other words, liposuction is a psychological burden on the thought that a surgeon is required to undergo an operation because the surgeon must visit the hospital to perform the operation, and the surgeon feels a financial burden depending on the operation cost.

In addition, since the liposuction treatment removes the fat through surgery, the body suffers from a problem, and there is a problem of side effects due to the yo-yo phenomenon by removing a large amount of fat in a short time. Therefore, there is a need to develop a technique that can treat obesity without any burden on the body and without the burden of cost.

Thus, Korean Patent Laid-Open Publication No. 2012-59078 discloses a device for removing fat cells in an obesity region by using autologous cell death of adipocytes by cooling the skin surface for a long time. However, the above-mentioned lipolysis apparatus is difficult to efficiently decompose fat due to its contact area with the flat skin surface, so that only the target region to be fat-decomposed is adsorbed by vacuum pressure separately.

This cooling fat decomposition is a structure in which a target portion is cooled by a Peltier effect by using a thermoelectric element and heat is emitted from the opposite side of the thermoelectric element and a separate device for dissipating the heat radiated from the thermoelectric element is provided, Cooling type using a liquid and an air-cooling type using air, and the cooling efficiency is deteriorated because the thermoelectric element and the water-cooling and air-cooling type heat radiating parts are separated by the piping, thereby increasing the size of the device in order to increase the cooling efficiency do.

Therefore, in order to solve such a problem of the conventional cooling fat decomposition apparatus, there is a growing demand for a heat dissipating unit integral type cooling fat decomposition apparatus that integrates the heat dissipation function into the cooling fat decomposition apparatus to make the apparatus compact and easy to carry.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a cooling fat decomposition apparatus having a heat dissipating unit for dissipating heat generated in a thermoelectric element to the outside, So that it is easy to carry.

According to an aspect of the present invention, there is provided a vacuum cleaner comprising: a suction part for sucking an object into a receiving space; and a suction part for sucking a target part to an inner side wall of the receiving space of the suction part by generating vacuum pressure in the receiving space. A cooling part for cooling a target part to which a cooling element is mounted on inner walls on opposite sides of the suction part to be sucked into the receiving space of the suction part; A heat dissipation unit for absorbing heat and radiating heat to the outside; and a case for accommodating the heat dissipation unit, wherein the upper case has a lid formed at one side of the case to discharge heat radiated from the heat dissipation unit to the outside.

The heat dissipating unit includes a heat exchanging body that is closely attached to an outer surface of the cooling element to absorb heat generated in the cooling element, a heat exchanging body having one side connected to the heat exchanging body and the other side extending upwardly from the heat exchanging body, A plurality of heat dissipating fins disposed at a lower portion of the heat sink, and a plurality of heat dissipating fins disposed at a lower portion of the plurality of heat dissipating fins, And a radiator fan for radiating air to the radiator.

Further, the present invention is further provided with a packing member, which is elastic, and is coupled to surround the lower end outer edge of the suction portion and closely attached to the surface of the object.

A first latching protrusion protruded outward along the outer edge of the suction section is formed at a lower end of the suction section. The first latching protrusion is spaced apart from the first latching jaw by a predetermined distance, And a fitting protrusion is formed on an inner surface of an upper end of the packing member to be engaged with the fitting groove. The packing member may include a first protrusion, And the packing member is elastically deformed to insert the fitting protrusion into the fitting groove.

Further, the inner surface of the suction cover is coupled to the outer surface of the suction unit such that the heat exchange body is housed inside and the heat exchange body is brought into close contact with the outer surface of the cooling element so that the inner surface presses the outer surface of the heat exchange body. .

The inner surface of the suction cover is coupled to the outer surface of the suction unit so that the heat exchange body is housed inside and the heat exchange body is brought into close contact with the outer surface of the cooling element so that the inner surface presses the outer surface of the heat exchange body. And a lower end surface of the close cover is coupled to an outer surface of the suction portion so as to cover a predetermined portion of the fitting groove portion through the second engaging jaw.

The heat exchange tubes are connected to the heat exchange body in a plurality of ways, the first heat exchange tubes are distributed to the upper portion of the heat exchange body on both sides along the longitudinal direction of the suction portion, and are distributed in one direction, The heat sink includes a first heat sink installed along the longitudinal direction of the first heat exchange tube and a second heat sink installed along the longitudinal direction of the second heat exchange tube, The heat dissipation fan includes a first heat dissipation fan installed at a lower portion of the first heat sink and a second heat dissipation fan installed at a lower portion of the second heat sink.

In addition, the louver has a plurality of flat plate-shaped plates having a predetermined length on the upper surface of the upper case in parallel from one side to the other side at regular intervals, Are inclined at an angle so as to face each other.

According to the present invention as described above, it is possible to improve the cooling efficiency, reduce the size of the apparatus, and make the portable unit easy to use by simply joining the heat radiating unit for radiating the heat generated in the thermoelectric element to the upper part of the suction unit. There is an effect that can be.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing the outline of a heat dissipating unit integral type cooling fat decomposition apparatus according to the present invention; FIG.
FIG. 2 is a front view of a heat dissipating unit integral type cooling fat decomposition apparatus according to the present invention.
FIG. 3 is a plan view showing a heat dissipating unit integral type cooling fat decomposition apparatus according to the present invention.
4 is a side view showing a heat dissipating unit integral type cooling fat decomposition apparatus according to the present invention.
5 is a cross-sectional view taken along the line A-A 'in Fig.
6 is a view showing a cross-sectional structure taken along a line B-B 'in FIG.
7 is a cross-sectional view taken along the line C-C 'in Fig.
8 is a view showing the structure of various packing members according to the present invention.
9 is a view showing a structure of a close cover according to the present invention.
10 is a view showing the structure of the bottom of the suction part in a state in which the close cover is mounted.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing the outline of a heat dissipating unit integral type cooling fat decomposition apparatus according to the present invention, FIG. 2 is a view showing a front structure of a heat dissipating unit integral type cooling fat decomposition apparatus according to the present invention, FIG. 4 is a side view of a heat dissipating unit integrated type fat-and-oil separator according to the present invention, and FIG. 5 is a cross-sectional view taken along line A-A ' FIG. 6 is a sectional view taken along the line B-B 'in FIG. 3, FIG. 7 is a sectional view taken along the line C-C' in FIG. 3, Fig. 9 is a view showing a structure of a close cover according to the present invention. Fig.

The heat dissipating unit integral type cooling fat decomposition apparatus according to the present invention includes a suction unit 10, a vacuum suction unit 20, a cooling unit 30, a heat dissipation unit 40, an upper case 50, (60) and a close cover (70).

The suction portion 10 is formed in a socket shape so as to be able to suck an object into the accommodation space. At this time, the bottom surface of the suction portion 10 can be designed in a round shape so as to facilitate contact with the target portion T. [ Since the suction portion 10 is designed to abut the skin tissue 1 of the human body, it is preferably formed of a biocompatible material, for example, a titanium material can be used.

The present invention further includes a packing member 60 coupled to the lower end of the suction unit 10 so that the target portion T is brought into close contact with the surface of the packing member 60. The packing member 60 is made of an elastic material such as silicon and is formed so as to surround the lower end outer edge of the suction portion 10 and the fitting projection portion 61 is formed on the upper inner side surface of the packing member 60 with a packing member 60 As shown in Fig. In addition, the packing member 60 may be shaped so as to correspond to various shapes of the target portion T so as to be detachably attached to the target portion. For example, the packing member 60 of Fig. 8A has both ends open and the central portion has a depressed shape, which is easy to apply to the skin such as the abdomen, and the packing member 60 of Fig. The packing member 60 of FIG. 8C is formed so that both side surfaces are recessed inward, and is used in close contact with the longitudinal direction of an arm or a leg.

A first stopping protrusion 11 protruding outward along the outer edge of the suction section 10 is formed at the lower end of the suction section 10 and a first stopping protrusion 11 A second locking protrusion 12 protruding outward along the outer edge of the suction unit 10 is formed at a predetermined distance from the first locking protrusion 11 and the second locking protrusion 12, The fitting groove portion 13 into which the fitting projection portion 61 of the packing member 60 is inserted is formed.

In order to couple the packing member 60 to the lower end of the suction unit 10, the user pulls both sides of the packing member 60 and stretches the fitting projection 61 of the packing member 60 to the first engaging jaw 11), and is seated in the fitting groove portion (13).

The vacuum suction unit 20 is installed so as to communicate with the inner ceiling of the suction unit 10 and generates a constant vacuum pressure inside the accommodation space to absorb the target site T. [ 6, the vacuum suction unit 20 may include a vacuum generating unit 21 for generating a vacuum pressure and a vacuum hole 22 for receiving a vacuum pressure from the vacuum generating unit 21. At this time, the vacuum hole 22 may be installed to communicate with the inner ceiling of the vacuum suction unit 20 and extend to a receiving space disposed in the center of the suction unit 10.

6, the cooling unit 30 mounts the cooling element 31 on opposite inner wall surfaces of the suction unit 10 to cool the target portion T that is absorbed into the suction unit 10. The cooling portion 30 is attached to one surface of the cooling element 31 and is brought into close contact with the surface of the target portion T to be heat-exchanged with the cooling element 31 and adsorbed to the inside of the suction portion 10, And a cooling plate 32 for transferring heat.

5, a heat dissipating unit 40 is provided on the other surface of the cooling device 31 to which the cooling plate 32 closely contacts, that is, on the outer surface of the cooling device 31 to perform heat exchange A heat exchanging tube 42 connected to one side of the heat exchanging body 41 to heat the heat absorbed by the heat exchanging body 41 through the heat exchanging medium and a heat exchanging tube 42 disposed in the longitudinal direction of the heat exchanging tube 41, And a heat radiating fan 44 for supplying circulated air to the sink 43 and the heat sink 43. [

One surface of the heat exchanging body 41 has a size corresponding to the size of the cooling element 31 so that one surface of the heat exchanging body 41 is closely attached to the cooling element 31 to absorb the heat generated in the cooling element 31, The heat exchange tube 42 is preferably made of a material having a high thermal conductivity so as to smoothly absorb heat, and the heat exchange tube 42 is formed by heat- And extends to the inside of the body 41 to form a flow path.

A plurality of heat exchanging tubes 42 are connected to the heat exchanging body 41 so that a single tube extends to the upper portion of the heat exchanging body 41. As shown in the figure, A plurality of heat exchange tubes (42) are divided along the longitudinal direction to distribute the heat transfer medium. Here, the heat exchange pipe 42 includes a first heat exchange pipe 42a directed toward one side of the suction section 10 and a second heat exchange pipe 42b directed toward the other longitudinal direction of the suction section 10 .

The heat exchange tubes 42a and 42b distributed to both sides of the heat exchanging body 41 extend along a longitudinal direction of the suction unit 10 and the heat sink 43 is connected to the first heat exchange tube 42a A first heat sink 43a to which a plurality of heat dissipating fins 42 'are coupled along the longitudinal direction and a second heat sink 42' to which a plurality of heat dissipating fins 42 'are coupled along the longitudinal direction of the second heat exchanging tube 42b 43b.

 The heat dissipating fan 44 includes a first heat dissipating fan coupled to a lower portion of the first heat sink 43a to supply air upward and a second heat dissipating fan 44b coupled to a lower portion of the second heat sink 43b, . The heat dissipation fan 44 is configured to allow air to flow between the heat dissipation fins 43 'below the heat sink 43 to enhance the heat dissipation effect.

The upper case 50 is coupled to the upper portion of the suction unit 10 and houses a heat sink 43 disposed on both sides of the heat exchange tubes 42a and 42b. A louver 51 is formed on the upper side of the upper case 50 on which the heat radiating fins 43 'are installed so that heat radiated from the heat sink 43 flows through the louver 51 to the outside of the upper case 50 . That is, the air blowing from the heat radiating fan 44 passes through between the radiating fins 43 'to absorb heat, and the hot wind is discharged through the louver 51 disposed in the upper chamber.

The louver 51 is provided with a plurality of flat plates 51a having a predetermined length at regular intervals in parallel from one side to the other. In the present invention, the flat plate 51a is provided on both sides of the louver 51 So as to face each other toward the center of the louver. That is, due to the inclination of the plate-like plate 51a, hot winds emitted from the inside to the outside of the upper case 50 are discharged to the outside from both sides of the louver 51, So that the hot air is canceled to some extent at the upper portion of the louver 51.

An operation unit 52 is provided on one side of the upper surface of the upper case 50, on which an operation button for allowing the user to operate the apparatus and a display screen are formed.

9, the close cover 70 includes a heat exchange body 41 attached to both sides of the suction section 10, and a bolt hole 71 formed on the outer side of the close cover 70, The tightening cover 70 is fitted to the outer surface of the suction part 10 and the heat exchange body 41 is fitted to the outer surface of the cooling element 31 So that the inner surface of the close-up cover 70 is pressed against the outer surface of the heat exchange body 41 by the fixing means 72 so as to be closely contacted. To this end, a lattice-shaped contact wall portion 73 is formed on the inner surface of the close cover 70 so that the close contact wall portion 73 is partially brought into close contact with the outer surface of the heat exchange body 41, So as to evenly apply pressure to the entire surface of the heat exchanging body 41.

10 shows a bottom structure of the suction part in a state in which the close cover is mounted. Referring to FIG. 10, the lower end surface of the close cover 70 passes through the second engaging jaw 12 of the suction part 10, (10) so as to cover a certain portion of the groove (13). Accordingly, in order for the packing member 60 to be coupled to the lower end of the suction unit 10, when the user extends the fitting protrusion 61 of the packing member 60 in the longitudinal direction so that the thickness of the fitting protrusion 61 becomes thin The fitting protrusion 61 is pushed into the space between the lower end surface of the close cover 70 and the gap of the fitting groove 13 of the suction unit 10 so that the fitting protrusion 61 is resiliently restored to a predetermined thickness, Is fixed to the lower end of the suction part (10). Due to the engagement position of the close cover 70, the packing member 60 is not easily dropped off by the vacuum pressure acting inside the suction unit 10. [

Hereinafter, an operation method of the heat dissipating unit integral type cooling fat decomposition apparatus according to the present invention will be described in detail.

First, the user visually confirms the surface state of the target portion T to be cooled and then selects the packing member 60 to be coupled to the lower end of the suction portion 10. Here, the packing member 60 may be provided in various shapes such as a shape in which the bottom surface is doubled in both sides or a center portion is doubled in shape.

At this time, the packing member 60 is made of a material such as silicone having elasticity, which allows the user to stretch the upper end of the packing member 60, The member 60 passes through the lower first stopping jaw 11 of the suction part 10 and one side of the fitting projection 61 formed inside the upper end of the packing member 60 is inserted into the fitting groove 13 , And is engaged with the fitting groove portion (13) continuously while pushing the fitting projection portion (61) from the inside of the packing member (60) with the user's finger.

After the vacuum pump 20 is brought into close contact with the target portion T to which the in-phase-preventing pad 80 is attached, So that the target portion T is brought into contact with the cooling plate 32 mounted on the inner side wall of the suction portion 10. Then, power is supplied to the cooling element 31 so that the target portion T is cooled for a predetermined time on the cooling plate 32, which is heat-exchanged by the cooling element 31, to perform lipolysis.

This method uses the self-apoptosis of adipocytes to remove adipocytes from the obesity region. When the adipocytes are continuously exposed to a cold temperature, they become natural necrosis by the death of self-apoptosis. In order to induce autologous cell death of the adipocyte, the adipocyte should be cooled at a temperature of 0 to -10 DEG C for 30 to 60 minutes, and the user should cool the adipocyte through the manipulation part 52 formed in the upper case 50 And the time value can be arbitrarily set within the time value range. However, when the user sets the temperature value and the time value out of the appropriate temperature value and the time value, the user can not set the setting value as the warning And an alarm is generated.

In addition, if there is no frostbite pad (80) to prevent frostbite and the minimum temperature and maximum usage time are set in advance and the frostbite pad (80) is not used during the procedure, It is possible to automatically stop the function and to control the completion of the function through voice or the like.

The cooling plate 32 is attached to one surface of the cooling element 31 and is cooled by the Peltier effect so that the other side of the cooling element 31 rises in temperature and releases heat through the heat dissipation unit 40.

To this end, a heat exchanging body 41 made of a copper material having a high thermal conductivity is closely attached to the other side of the cooling element 31 to absorb the heat generated in the cooling element 31. A plurality of heat exchange tubes (42) are introduced into the heat exchange body (41) and heat exchanged by a heat transfer medium moving inside the heat exchange tube (42). The heat transfer medium thus exchanged is moved to the other side along the heat exchange pipe 42 and the heat is discharged to the outside by the heat radiation fins 43 'of the heat sink 43 coupled to the other side of the heat exchange pipe 42.

The heat radiated to the space between the heat dissipation fins 43 'is radiated by the heat dissipation fan 44 installed at the bottom of the heat sink 43 so that the air passes between the heat dissipation fins 43' The hot air discharged to the top of the heat sink 43 is discharged to the outside through the louver 51.

The hot air discharged to the outside through the louver 51 is prevented from being dispersed to the outside due to the inclination of the plate-like plate 51a so as to be gathered from both sides of the louver 51 to the upper center, do.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. Accordingly, the scope of the appended claims should include all such modifications and changes as fall within the scope of the present invention.

10: Suction part 11: First stopping jaw
12: second locking jaw 13: fitting groove portion
20: vacuum suction unit 21: vacuum generating unit
22: Vacuum hole
30: cooling section 31: cooling element
32: cooling plate
40: heat dissipating unit 41: heat exchanging body
42: heat exchange tube 42a: first heat exchange tube
42b: second heat exchange tube 43: heat sink
43a: first heat sink 43b: second heat sink
43 ': heat sink fin 44: heat sink fan
44a: first radiating fan 44b: second radiating fan
50: upper case 51: louver
51a: Plate-type plate 52:
60: packing member 61:
70: close cover 71: bolt hole
72: fixing means 73:
80: Anti-frost pad

Claims (8)

A suction part for sucking an object into the accommodation space;
A vacuum suction unit for generating a vacuum pressure inside the accommodation space and adsorbing the target site to the inner side wall of the accommodation space of the suction unit;
A cooling unit for cooling a target portion to be adsorbed to the inside of the receiving space of the suction unit, the cooling unit being mounted on opposite inner walls of the suction unit;
A heat exchange body disposed at an upper portion of the suction portion to absorb heat generated from the cooling element and dissipate heat to the outside while being in close contact with the outer surface of the cooling element to absorb heat generated in the cooling element; A heat exchanger tube connected to the heat exchange body and having a second side extending upwardly from the heat exchange body and having a heat transfer medium therein, and a plurality of heat dissipation fins in a longitudinal direction of the heat exchange tube, And a heat dissipating unit installed at a lower portion of the heat sink and radiating air upward from a lower portion of the plurality of heat dissipating fins;
A case for accommodating the heat-radiating portion, the upper case having a louver formed at one side of the case to discharge heat radiated from the heat-radiating portion to the outside; Including,
Wherein the louver is provided with a plurality of flat plates having a predetermined length on the upper surface of the upper case in parallel from one side to the other side at regular intervals, Wherein the heat dissipating unit integral type cooling fat decomposition apparatus is installed so as to incline at a predetermined angle so as to face each other.
delete The method according to claim 1,
Further comprising a packing member coupled to the outer edge of the lower end of the suction portion so as to be in close contact with the surface of the object, the material having elasticity.
The method of claim 3,
A first latching protrusion protruding outwardly along an outer edge of the suction portion is formed at a lower end portion of the suction portion and is protruded outward along an outer edge of the suction portion at an upper portion of the first latching jaw, And a fitting groove is formed between the first engaging jaw and the second engaging jaw,
Wherein a fitting protrusion to be fastened to the fitting groove portion is protruded inward along the inner edge of the packing member on the inner surface of the upper end portion of the packing member so that the packing member is elastically deformed to insert the fitting protrusion into the fitting groove portion. A heat dissipating unit integral type cooling fat decomposition apparatus.
The method according to claim 1,
And a tight cover coupled to the outer surface of the suction portion by the fixing means so that the heat exchange body is housed inside and the heat exchange body is in close contact with the outer surface of the cooling element so that the inner surface presses the outer surface of the heat exchange body And the heat dissipating unit integral type cooling fat decomposition apparatus.
5. The method of claim 4,
And a tight cover coupled to the outer surface of the suction portion by the fixing means so that the heat exchange body is housed inside and the heat exchange body is in close contact with the outer surface of the cooling element so that the inner surface presses the outer surface of the heat exchange body However,
And the lower end surface of the close cover is coupled to the outer surface of the suction portion so as to cover the predetermined portion of the fitting groove portion through the second stopping protrusion.
The method according to claim 1,
Wherein the heat exchange tubes are connected to the heat exchange body in a plurality of ways, the first heat exchange tubes being distributed to both sides of the heat exchange body along the longitudinal direction of the suction section, the first heat exchange tubes being distributed in one direction, Tube,
The heat sink includes a first heat sink installed along the longitudinal direction of the first heat exchange tube and a second heat sink installed along the longitudinal direction of the second heat exchange tube,
Wherein the heat dissipating fan includes a first heat dissipating fan provided below the first heat sink and a second heat dissipating fan provided below the second heat sink.
delete

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