KR101723211B1 - Apparatus for cooling adipolysis having the foreign substances inflow prevention function - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling fat decomposition apparatus that evaporates moisture generated from a frost protection pad by vacuum pressure to be formed into a water droplet on an inner side wall of a suction section so as not to be introduced into a vacuum suction section by vacuum pressure, A sucking portion for sucking an object into the accommodating space in a socket shape in which a receiving space is formed; a suction portion provided in communication with a ceiling of the suction portion to generate a vacuum pressure in the receiving space, A cooling part for cooling a target part to be sucked to the inside of the receiving space of the suction part by mounting a cooling element on opposite inner walls of the suction part, and a pad attached to the target part, Is interposed between the cooling part and the target part to prevent the frost on the target part when cooled by the cooling part Wherein the inner side surface of the suction portion is sealed so that the moisture contained in the in-phase preventing pad is evaporated by the vacuum pressure to be formed as water droplets on the inner side wall of the suction portion, And an inflow prevention cap for preventing the water droplets from being introduced into the vacuum suction unit.
According to the present invention, the moisture contained in the in-phase-preventing pad is evaporated in the cooling fat-dissolving process, and water drops collected in the inner side wall of the suction part are sealed by the inflow prevention cap, So that the suction force is not weakened and the occurrence of device failure due to the inflow of foreign substances into the vacuum suction unit can be reduced.

Description

TECHNICAL FIELD [0001] The present invention relates to a cooling fat decomposition apparatus having a foreign matter inflow prevention function,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cooling fat decomposition apparatus that prevents moisture generated in a frost protection pad from evaporating due to vacuum pressure to be formed into water droplets on the inner side wall of a suction section, The present invention relates to a cooling fat decomposition apparatus having a function of preventing foreign matter from flowing into a vacuum suction unit by means of an inflow preventing cap for sealing the inner side surface of the suction unit so that water droplets conveyed to the ceiling along the inner surface of the suction unit are prevented from flowing into the vacuum suction unit.

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 small contact area due to the contact of the cooling site with the flat skin surface. In particular, since the skin surface needs to be cooled for a long time, there is a serious problem .

In order to prevent frostbite, the anti-frost pad is covered on the skin of the target area, and then the top of the frostbite pad is cooled.

However, such a cooling fat decomposition apparatus has been widely used for home use, and users who do not know the proper method of use frequently use the cooling fat decomposition apparatus without the use of the frost protection pad, It is the situation that is happening.

In order to solve such a problem, Patent Application No. 2014-0169404 filed by the present applicant discloses that the frostbite pad is attached to the target site so that frostbite can be prevented even if the target site with the frostbite pad is cooled for a long time.

However, in the process of cooling the target site for a long time, the moisture contained in the anti-frost pad evaporates into the suction part and is collected as water droplets on the inner side wall of the suction part. Such water droplets are discharged to the upper part along the inner side wall of the suction part The suction force is reduced through the vacuum suction hole connected to the ceiling of the suction part while being conveyed, and there is a high possibility that the device may be broken due to the flow of foreign matter.

Therefore, it is possible to overcome the unreasonableness of the conventional cooling-fat decomposition apparatus with the conventional frost protection pad and to prevent the water droplets generated in the suction section from flowing into the vacuum suction section during the cooling process for a long time, There is a growing demand for a cooling fat decomposition apparatus capable of preventing malfunctions in advance.

Korea Patent Publication No. 2012-59078

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a method and a device for preventing moisture from evaporating, Thereby preventing the refrigerant from being introduced into the suction portion.

According to an aspect of the present invention, there is provided a suction apparatus including: a suction unit for sucking an object into a receiving space in the form of a socket having a receiving space formed therein; A vacuum suction unit for generating a vacuum pressure in the space to absorb the target portion to the inner side wall of the receiving space of the suction unit; and a cooling unit mounted on the inner walls of opposite sides of the suction unit for adsorption to the inside of the receiving space of the suction unit And an anti-frost pad interposed between the cooling section and the target site to prevent frost from the target site during cooling by the cooling section, The apparatus according to any one of claims 1 to 3, wherein the suction port And an inflow prevention cap for preventing the water droplets from entering the inside of the vacuum suction unit when the water contained therein evaporates and is formed as water droplets on the inner side wall of the suction unit.

Wherein the inflow prevention cap is formed in a shape corresponding to an inner side surface shape of the suction portion on the rim of the inflow prevention cap and is closely attached to the inner side surface of the suction portion and extends integrally with the close contact portion, And a sloping falling guide wall portion.

In addition, a through hole is formed at one side of the inflow preventing cap so that the suction air is sucked from the vacuum suction unit through the through hole.

In addition, an engagement protrusion is formed on the inner side of the inflow prevention cap at a predetermined interval, and a coupling protrusion protruding downward is formed on a ceiling of the suction section in a position corresponding to the engagement protrusion. And is resiliently coupled while sliding on the engaging projections.

Furthermore, a gripping portion is formed at the lower end of the inflow preventing cap.

In addition, the vacuum suction unit is formed with a vacuum hole communicating with the ceiling of the suction unit, and the suction unit is formed with a blocking wall extending to the inside of the suction unit so as to surround the vacuum hole.

According to the present invention, the moisture contained in the in-phase-preventing pad is evaporated in the cooling fat-dissolving process, and water drops collected in the inner side wall of the suction part are sealed by the inflow prevention cap, So that the suction force is not weakened and the occurrence of device failure due to the inflow of foreign substances into the vacuum suction unit can be reduced.

1 is a perspective view of a cooling fat decomposition apparatus having a foreign matter inflow preventing function according to the present invention.
FIG. 2 is a cross-sectional view illustrating a state in which a cooling fat decomposition apparatus having a function of preventing foreign matter inflow according to the present invention adsorbs a target site.
3 and 4 are perspective views of the inflow preventing cap according to the present invention, as viewed from the top and bottom.
5 is a perspective view showing a cooling fat decomposition apparatus in a state in which the inflow prevention cap is detached.
FIG. 6 is a conceptual diagram illustrating a process of transferring water droplets generated in the suction part during the decomposition of cooling fat according to the present invention.
FIG. 7 is a conceptual diagram illustrating a process of transferring water droplets generated in the suction portion in a state where the rim portion of the suction portion closely contacting the target portion is located on the upper side and the ceiling of the suction portion is located on the lower side.

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

FIG. 1 is a perspective view of a cooling fat decomposition apparatus having a foreign material inflow prevention function according to the present invention, FIG. 2 is a sectional structure of a cooling fat decomposition apparatus having a function of preventing foreign matter inflow according to the present invention, FIGS. 3 and 4 are perspective views of the inflow prevention cap according to the present invention as viewed from the top and bottom, and FIG. 5 is a perspective view illustrating a cooling fat decomposition apparatus with the inflow prevention cap removed.

The cooling fat decomposition apparatus according to the present invention includes a suction unit 10, a vacuum suction unit 20, a cooling unit 30, a frost protection pad 40 and an inflow prevention cap 50, do.

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, it is preferable that the bottom surface of the suction unit 10 is 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 vacuum suction unit 20 is installed to communicate with the inner ceiling of the suction unit 10 to generate vacuum pressure inside the accommodation space to adsorb the target site T. [ The vacuum suction unit 20 includes a vacuum hole 21 for receiving vacuum pressure from a vacuum generating unit for generating a vacuum pressure and the vacuum hole 21 is arranged to communicate with the inner ceiling of the vacuum suction unit 20 And is extended to a receiving space disposed in the center of the suction portion 10.

The cooling unit 30 is provided with cooling devices 32 on the opposite inner walls of the suction unit 10 to cool the target portion T to be absorbed into the suction unit 10. The cooling unit 30 includes a cooling plate 31 attached to one surface of the cooling element and being in close contact with the surface of the target portion T to be adsorbed to the inside of the suction unit 10 so as to exchange heat with the cooling element, And a heat dissipating unit attached to the other surface of the cooling device to emit heat generated in the cooling device.

Here, the cooling element may be composed of an n-type thermoelectric semiconductor and a p-type thermoelectric semiconductor, and the n-type and p-type thermoelectric semiconductors are electrically connected in series and thermally connected in parallel. In this case, the cooling element uses the Peltier effect in which heat is absorbed in the n-type thermoelectric semiconductor and heat is generated in the p-type thermoelectric semiconductor when power is supplied, so that the target portion (T) And radiates heat to the opposite side through the heat radiating portion 33.

The frost protection pad 40 is a pad which is attached to a target portion T of the skin for lipolysis and which is interposed between the cooling portion 30 and the target portion T so that the target portion T is located on the cooling plate 31, So as to prevent frostbite on the surface of the skin. The anti-frost pad 40 is a gel type having a certain moisture content and is composed of components such as hydroxyethyl cellulose, propylene, glycerin, sorbitol, parfume, and pure water

The inflow preventing cap 50 is provided to seal the inner side surface of the suction portion 10 so that the moisture contained in the in-phase preventing pad 40 is evaporated during the cooling fat dissolving process and is collected on the inner side wall of the suction portion 10 The water droplets that are formed by the air pressure are prevented from being transferred to the ceiling of the suction unit 10 along the inner side wall of the suction unit 10 by the vacuum air pressure to be introduced into the vacuum suction unit 20.

2, the inflow prevention cap 50 is formed at the edge of the inflow prevention cap 50 in a shape corresponding to the inner side shape of the suction portion 10, (51), and a drop guide wall portion (52) extending integrally with the close contact wall portion (51) and inclined downward inward. That is, the inner side wall of the suction part 10 is a wall surface inclined upwardly inward, and the close-contact wall part 51 is formed in the ceiling of the suction part 10 in close contact with the inner side wall of the suction part 10, Thereby preventing water droplets from flowing into the vacuum hole 21. The water droplets which come into contact with the outer surface of the close-contact wall portion 51 are conveyed downward along the inclined fall-inducing wall portion 52 extending integrally with the close-contact wall portion 51, . In addition, foreign matter such as fluid having a certain moisture generated in the skin other than the water droplets generated by the frost protection pad 40 is prevented from entering.

At least one through hole 53 is formed at one side of the inflow preventing cap 50 so that the air in the suction part 10 is sucked into the vacuum adsorption part 20 through the through hole 53. In this way, the rim of the inflow prevention cap 50 is in close contact with the ceiling portion of the suction unit 10 to form a hollow space therein so that the inflow prevention cap 50 can communicate with the suction unit 10 only through the through- 53, the through hole 53 does not directly communicate with the vacuum hole 21, so that the water hole can not be easily introduced into the vacuum hole 21. [

 A locking protrusion 54 protrudes upward from the inflow prevention cap 50 at a predetermined interval and is formed at a ceiling of the suction unit 10 with a coupling protrusion 11 are protruded and the engaging protrusions 54 slide on the engaging protrusions 11 so that the engaging protrusions 54 disposed on both sides are elastically deformed and engaged.

A gripping portion 55 is formed at the lower end of the inflow preventing cap 50 so that the user can pull the inflow preventing cap 50 while the user grips the gripping portion 55, So as to be easily detachable and detachable.

The suction hole 10 communicates with the vacuum hole 21 and is formed with a blocking wall 12 extending to the inside of the suction hole 10 so as to surround the vacuum hole 21, When the suction part 10 is positioned on the upper side and the ceiling of the suction part 10 is positioned on the lower side, water droplets that are conveyed downward along the inner side wall of the suction part 10 by the vacuum pressure, Even if water drops falling directly without being conveyed along the wall of the suction part 10 are introduced into the inflow prevention cap 50 through the through holes 53, Avoid direct entry into the interior.

Hereinafter, the function of the inflow prevention cap in the process of decomposing the cooling fat according to the present invention will be described in detail.

FIG. 6 is a conceptual diagram illustrating a process of transferring water droplets generated in the suction part during the decomposition of cooling fat according to the present invention.

First, in the cooling fat decomposition method according to the present invention, a socket-shaped suction portion 10 is disposed on an upper portion of a target portion to which the in-phase-preventing pad 40 is attached, and then a vacuum suction portion 20 The target portion T is brought into contact with the cooling plate 31 mounted on the inner side wall of the suction portion 10 so as to cool the target portion T by lifting the portion T to the inside of the suction portion 10 .

At this time, since the in-phase prevention pad 40 adsorbed by the vacuum pressure inside the suction part 10 contains a lot of moisture in the gel state, the moisture contained in the in-phase prevention pad 40 during the cooling fat- Water is collected in the inner side wall of the suction unit 10 and is formed into water droplets. This water droplet is conveyed upward along the inner side wall of the suction portion 10 by the suction force of the vacuum suction portion 20. [

The water droplets thus transferred are prevented from being transferred to the upper ceiling of the suction unit 10 along the inner side wall of the suction unit 10 by the inflow prevention cap 50 closely attached to the suction unit 10, .

More specifically, the air in the suction part 10 is press-fed to the vacuum suction part 20 provided on the ceiling of the suction part 10 through the through hole of the inflow prevention cap 50, The water droplets which are attached to the face wall and transported upward along the wall surface are not further conveyed upward by the close contact wall portion 51 which is in close contact with the inner face wall of the suction portion 10, (52). The water droplets conveyed to the fall-inducing wall portion 52 fall down smoothly downward along the inclined surface of the fall-inducing wall portion 52.

In this way, it is possible to prevent the water droplets or the like, which are floating in the suction part 10 or the moisture remaining on the skin surface, from flowing into the vacuum suction part 20 by the vacuum pressure so that the suction force is not weakened, .

In addition, in the above description, the ceiling of the suction unit 10 is located at the upper portion to cool the target portion T. In the following description, the inflow prevention in the state where the ceiling of the suction unit 10 is located at the lower side The operation of the cap 50 will be described in detail.

FIG. 7 is a conceptual diagram illustrating a process of transferring water droplets generated in the suction portion in a state where the rim portion of the suction portion closely contacting the target portion is located on the upper side and the ceiling of the suction portion is located on the lower side.

6, when the suction part 10 is disposed in the opposite direction to that of FIG. 6, the water droplets formed by the moisture generated inside the suction part 10 are formed on the inner side wall by the vacuum suction part 20, And is further downwardly conveyed along the inner side wall of the suction section 10 by the urging force. The droplets thus conveyed are collected in the space between the inner side wall of the suction portion 10 inclined in mutually opposite directions and the falling guide wall portion 52.

The amount of water droplets generated inside the suction section 10 and conveyed downward along the inner wall surface of the suction section 10 is collected in the space between the inner side wall of the suction section 10 and the falling guide wall section 52 But may be introduced into the ceiling of the suction unit 10 through the through-holes 53 of the surface of the inflow preventing cap 50 if exceeded. In addition to the water droplets generated on the inner side wall of the suction unit 10, water droplets that are generated on the frost protection pad 40 and fall directly into the air are prevented from entering into the through- So that it can be introduced into the ceiling of the suction part 10. [ The water droplets flowing into the ceiling of the suction unit 10 are blocked by the blocking wall 12 so as not to be introduced into the vacuum hole 21. [

The foreign object such as water drops flowing into the inner surface of the inflow prevention cap 50 is pulled by the user while gripping the grip portion 55 and is guided by the engagement protrusion 54 of the inflow prevention cap 50 Is elastically changed and is easily detached and removed to clean the foreign matter.

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: Coupling projection
12: blocking wall
20: Vacuum suction part 21: Vacuum hole
30: cooling section 31: cooling plate
40: Anti-frost pad
50: inflow prevention cap 51:
52: falling guide wall 53: through hole
54: engagement jaw 55:

Claims (6)

A sucking portion for sucking an object into the accommodating space in a socket shape having an inner space formed therein; and a suction portion provided in communication with the ceiling of the suction portion to generate vacuum pressure inside the accommodating space, A cooling part for cooling a target part to be sucked to the inside of the receiving space of the suction part by a cooling element mounted on inner walls on opposite sides of the suction part, And an in-phase preventing pad interposed between the cooling part and the target part to prevent the in-phase of the target part during cooling by the cooling part,
So that moisture contained in the in-phase-preventing pad is evaporated by vacuum pressure to seal the inner side surface of the suction part, and water droplets are formed on the inner side wall of the suction part to prevent the water droplets from flowing into the vacuum suction part Further comprising an inflow-preventing cap,
The inflow-
A suction wall portion formed at an edge of the inflow preventing cap in a shape corresponding to an inner side surface shape of the suction portion and closely contacting the inner side surface of the suction portion,
And a falling guide wall portion extending integrally with the contact wall portion and inclined downward inward.
delete The method according to claim 1,
Wherein a suction hole is formed at one side of the inflow preventing cap so that the suction air is sucked from the vacuum suction unit through the through hole.
The method according to claim 1,
A protrusion protruding upward from the inflow prevention cap at a predetermined interval, and a coupling projection protruding downward at a position corresponding to the coupling protrusion is formed on the ceiling of the suction section,
Wherein the engaging jaw is resiliently coupled with the engaging protrusion while sliding on the engaging protrusion.
5. The method of claim 4,
And a grip portion is formed at a lower end of the inflow preventing cap.
The method according to claim 1,
Wherein the vacuum suction part is formed with a vacuum hole communicating with the ceiling of the suction part, and the suction part is formed with a blocking wall extending to the inside of the suction part so as to surround the vacuum hole. Lipolysis apparatus.

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