KR101580504B1 - Local Lipolysis System Using High-Pressure Carbon Dioxide And Chiller - Google Patents

Abstract

The present invention relates to a local lipolysis apparatus using high pressure carbon dioxide and a chiller which injects the carbon dioxide into subcutaneous fat and cools the subcutaneous fat to enhance removal efficiency of the subcutaneous fat. The present invention comprises: a gas supply device (200) pressurizing carbon dioxide to be supplied to a hand gun (100) and circulating chiller in the hand gun (100); and the hand gun (100) inserting an injection tube (114) into an internal hollow space (111) of a probe (110) provided with a needle (12) at an end which penetrates a skin (1) and gets inserted into the subcutaneous fat (2), injecting the carbon dioxide into the subcutaneous fat via the injection tube (114) and the needle (112), and recovering the chiller via the internal hollow space (111) after passing the injection tube (114) to cool the end of the probe (110) by circulating the chiller, whereas being provided with a valve unit (130) and a trigger (122) controlling the injection of the carbon dioxide and the circulation of the chiller such that the valve unit (130) is controlled to inject a predetermined amount of the carbon dioxide and to circulate the chiller for a predetermined time whenever the trigger (122) is pulled.

Description

(Local Lipolysis System Using High-Pressure Carbon Dioxide And Chiller)

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a local fat fusing device using carbon dioxide gas and a refrigerant, which inject carbon dioxide, air or a drug into subcutaneous fat and simultaneously cool subcutaneous fat to increase the removal efficiency of subcutaneous fat.

Reduction of subcutaneous fat present under the epidermis and dermis of the skin is one of the most important fields of cosmetic treatment and various treatment methods are used for the purpose of this cosmetic treatment.

The procedure for reduction of subcutaneous fat is liposuction which inserts a cannula into subcutaneous fat to inhale fat, refrigeration procedure which attaches cooling pad to skin surface to cool necrotizing subcutaneous fat, high frequency or ultrasound to subcutaneous fat tissue Carboxytherapy, which removes fat by accelerating blood circulation and lymphatic circulation of adipose tissue by slowly injecting carbon dioxide (CO ₂ ) into subcutaneous fat with an injection needle, by thermal heating to remove subcutaneous fat by irradiation. , And mesotherapy for injecting drugs for subcutaneous fat into obesity.

During these various procedures, the frozen operation is easy to perform, but the operation effect is low. In the patent publication 10-2011-0119640, an invasive procedure for inserting the cooled probe into the subcutaneous fat by circulating the refrigerant is used.

However, even if invasive cooling is used, the procedure time is shorter than that of non-invasive cooling. However, there is still a disadvantage that a considerably long operation time is required for necrosis of subcutaneous fat due to cooling.

On the other hand, carboxytherapy is a treatment for intensively treating a region where fat is excessively accumulated, and Patent No. 10-0772961 increases the fat removal efficiency by performing the mesotherapy and carboxytherapy operations, but here, Although a separate syringe needle is used, the internal structure is complicated and a separate incision is made by each needle, and a combined operation is presented, but a procedure for increasing the efficiency of the invasive cooling operation is not suggested.

KR 10-2011-0119640 A 2011.11.02. KR 10-0772961 B1 Oct. 29, 2007.

Therefore, it is an object of the present invention to provide a method and a device for improving the fat removal efficiency, shortening the procedure time, minimizing the incision and reducing the suffering of the recipient by using the invasive cooling procedure while simultaneously using the carbohydrate therapy, And to provide a local fat melting apparatus using the same.

In order to achieve the above object, the present invention provides a local fat fission apparatus using a high-pressure carbon dioxide gas and a coolant, comprising: a gas supply device (200) for supplying carbon dioxide to the hand gun (100) ); And the injection tube 114 is inserted into the hollow interior 111 of the probe 110 having the needle 112 at the end thereof inserted into the subcutaneous fat 2 through the skin 1 to inject carbon dioxide into the injection tube 114 And then flows into the subcutaneous fat 2 via the needle 112. The refrigerant is circulated through the injection tube 114 and then returned through the hollow interior 111 so that the end of the probe 110 is circulated through the refrigerant circulation And includes a valve unit 130 and a trigger 122 for controlling the injection of carbon dioxide and the circulation of the coolant so that the valve unit 130 is controlled every time the trigger 122 is pulled, And circulates the refrigerant for a preset time; And a control unit.

The injection tube 114 includes a gas pipe 114a inserted into the hollow interior 111 and connected to the needle 112 and a refrigerant pipe 114b inserted into the hollow interior 111 to reach the end of the probe 110 So that carbon dioxide is injected into the subcutaneous fat 2 through the gas pipe 114a and the needle 112 and the refrigerant is circulated through the refrigerant pipe 114b and the hollow interior 111. [

The hand gun 100 supplies carbon dioxide by a predetermined amount every time the trigger 122 is pulled and at the same time circulates the refrigerant for a preset time.

The inlet pipe 114 is formed of a single pipe leading to the end of the probe 110. The refrigerant is carbon dioxide and the valve unit 130 is connected to the inlet 110 of the probe 110 through a hollow interior 111 of the probe 110, An intermittent valve 130d for interrupting the path; And a switching valve 130c for selecting any one of carbon dioxide and refrigerant to be injected into the injection tube 114. When the carbon dioxide is injected into the injection tube 114, And opens the intermittent valve 130d when the refrigerant is injected into the injection pipe 114. [0051] As shown in FIG.

The valve 130 is inserted into the end of the plunger 135 with the other end of the piston rod 134 having the first piston 132 fixed to one end and the second piston 133 fixed to the middle, The plunger 135 is inserted into the inlet of the cylinder 131 so that the first piston 132 and the second piston 133 are disposed inside the cylinder 131 A carbonic acid gas injection port 131a for injecting carbon dioxide into the cylinder 131, a discharge port 131b connected to the injection pipe 114 and a refrigerant inlet port 131c for injecting the refrigerant into the cylinder 131, A refrigerant return port 131d connected to the hollow interior 111 of the probe 110 and a refrigerant return port 131d connected to the hollow interior 111 of the probe 110. The refrigerant return port 131d is connected to the inlet 131 of the probe 131, To the gas supply device 200 to be returned to the gas supply device 200 And a refrigerant discharge port 131e is formed.

When the coolant is circulated, the plunger 135 is pulled out of the cylinder 131 so that the first piston 132 and the second piston 133 are pulled, and the space between the other end closed and the first piston 132 And the coolant inlet port 131c and the coolant outlet port 131e are communicated with each other through the space between the first piston 132 and the second piston 133 and the coolant inlet port 131c and the outlet port 131b are communicated with each other through the space between the first piston 132 and the second piston 133 At the same time, the carbonic acid gas inlet 131a is communicated with the space between the second piston 133 and the plunger 135 to compress and store the carbon dioxide.

When the carbon dioxide is injected into the subcutaneous fat, the plunger 135 is pushed into the cylinder 131 to move the first piston 132 to the closed end of the cylinder 131, The space between the second piston 133 and the plunger 135 is communicated with the discharge port 131b while the discharge port 131e is closed and the refrigerant injection port 131c is closed by the second piston 133. Simultaneously, The carbonic acid gas inlet 131a is closed by the valve 135 and then only the plunger 135 is pushed to pressurize the carbon dioxide to be discharged to the discharge port 131b.

The probe 110 includes an inner protrusion 114 which locally presses an outer circumferential surface of a portion to be inserted into the subcutaneous fat 2 and protrudes to an inner circumferential surface of the probe 110. The hand gun 100 is inserted into an injection tube And a temperature sensor (123, 124) for detecting the difference between the temperature of the refrigerant injected into the hollow interior (111) and the temperature of the refrigerant circulated through the hollow interior (111). When the temperature difference is smaller than a preset error, The temperature of the supplied refrigerant is controlled so as to maintain a predetermined error by raising the temperature of the supplied refrigerant while maintaining the temperature of the supplied refrigerant within a predetermined range.

The present invention having the above-described structure can cool the subcutaneous fat after injecting carbon dioxide into the subcutaneous fat. Therefore, the effect of the cooling therapy can be obtained along with the effect of the carboxytherapy, and the effect of the cooling treatment can be doubled can do.

In addition, the present invention enables the injection of carbon dioxide and the cooling by the coolant through one incision 3, and the portion to be inserted into the subcutaneous fat is concentratedly cooled by the inner protrusion 114, The inner protrusion 114 can be easily formed while using a narrow probe because the outer surface of the inner protrusion 114 is formed by locally pressing the outer circumferential surface.

Also, since the present invention adjusts the cooling temperature of the subcutaneous fat by using the temperature difference between the supplied refrigerant and the reflux refrigerant, the temperature sensor may not be installed on the probe 110. Accordingly, Can be produced.

1 is a structural diagram of a local fat fusing apparatus using a high-pressure carbonic acid gas and a refrigerant according to a first embodiment of the present invention, and showing the hand gun 100 as a sectional view.
2 is an enlarged cross-sectional view of an end portion of the probe 110 shown in FIG.
Fig. 3 is a sectional view of the probe 110 shown in Fig. 1 in a state where the end portion of the probe 110 is inserted into the subcutaneous fat.
4 is a configuration diagram of a local fat fusing apparatus using a high-pressure carbonic acid gas and a coolant according to a second embodiment of the present invention, and is a sectional view of the hand gun 100. Fig.
5 is an enlarged sectional view of an end portion of the probe 110 shown in Fig.
FIG. 6 is a configuration diagram of a local fat fusing apparatus using a high-pressure carbon dioxide gas and a coolant according to a third embodiment of the present invention, and is a sectional view of the hand gun 100. FIG.
7 is an enlarged view of the valve unit 130 shown in Fig. 6, showing a state change in a sectional view according to a change in the position of the plunger 135 by the valve driving unit 140. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a cross-sectional view of the hand gun 100 shown in FIG. 1 and shows a state in which the body fat 120 is embedded in the body 120 according to an embodiment of the present invention. As shown in FIG.

FIG. 2 is an enlarged sectional view showing an end portion of the probe 110, and FIG. 3 is a sectional view showing a state where an end portion of the probe 110 is inserted into subcutaneous fat.

Referring to the drawings, a local fat fusing apparatus using a high-pressure carbonic acid gas and a coolant according to a first embodiment of the present invention includes a hand gun 100 to be hand-held, a pressurizing unit 120 for supplying carbon dioxide and a coolant to the hand gun 100, And a gas supply device 200 for circulating the refrigerant by recycling and re-cooling the refrigerant.

The hand gun 100 includes a probe 110 which is inserted into a layer in which the subcutaneous fat 2 is formed through the skin 1 and epidermis and the dermis 2 and a probe 110 for inserting carbon dioxide and a coolant supplied from the gas supply device 200 into the probe 110 A valve body 130 accommodated in the body 120 and interrupting the injection of carbon dioxide and a refrigerant is provided in the body 120. The body 120 is provided with a pipe to be connected to the gas supply device 200, .

First, the probe 110 is formed as a hollow tube as a whole. The end portion of the portion to be inserted into the subcutaneous fat 2 is closed. A needle 112 having a thin hollow tube shape is extended to the end portion And the other end of the opposite side is detachably fixed to the body 120, and the injection tube 114 is inserted into the hollow interior 111. The carbon dioxide is injected into the subcutaneous fat 2 through the needle 112 via the injection tube 114 and the refrigerant is circulated through the injection tube 114 and then returned through the hollow interior 111, Can be cooled by the refrigerant circulation.

In the first embodiment of the present invention, the injection tube 114 is inserted into the hollow interior 111 of the probe 110 and connected to the needle 112, and a gas pipe 114a connected to the hollow 112 of the probe 110 And a coolant pipe 114b inserted into the end of the probe 110 so as to inject carbon dioxide into the subcutaneous fat through a passage leading to the gas pipe 114a and the needle 112, So that the refrigerant can be circulated through the hollow interior 111.

At least one inner protrusion 113 is formed on the outer circumferential surface of the end portion of the probe 110, which is inserted into the subcutaneous fat 2, so as to protrude from the inner circumferential surface. Here, the term 'locally compressed' means that the protrusion is formed on the inner circumferential surface of the probe 110 by pressing the outer circumferential surface with a compression protrusion having a very small size compared to the outer diameter and length of the probe 110, But it forms a projection that does not stop the flow. Although only one inner protrusion 113 is shown in the drawing, the inner protrusion 113 may be formed at a plurality of locations along the circumferential direction of the end portion of the probe 110 or along the longitudinal direction, or may be formed spirally long.

The gas pipe 114a, the refrigerant pipe 114b and the hollow interior 111 are communicated one to one with the other internal pipes provided in the body 120 at the other end connected to the body 120. [

The body 120 is connected to the refrigerant circulation part 220 of the gas supply device 200 to communicate with the refrigerant pipe 114b through an inner pipe communicating with the hollow interior 111 of the pro 110, The inner pipe is connected to the coolant circulation unit 220 of the gas supply device 200 and the inner pipe communicating with the gas pipe 114a is connected to the carbon dioxide gas supply unit 230 of the gas supply device 200 And a valve portion 130 for interrupting the injection of carbon dioxide and the circulation of the refrigerant is also accommodated therein.

In the first embodiment of the present invention, the valve unit 130 injects carbon dioxide supplied from the gas supply device 200 into the gas pipe 114a to inject carbon dioxide into the subcutaneous fat 2, A first valve 130a for interrupting the injection and a refrigerant supplied from the gas supply device 200 to the refrigerant pipe 114b to pass through the hollow portion 111 of the prosuper 110, And a second valve 130b for controlling the injection of the refrigerant (or the circulation of the refrigerant) in circulating the refrigerant through the supply device 200.

The temperature of the refrigerant that is interrupted by the second valve 130b and injected into the refrigerant pipe 114b is measured by the first temperature sensor 123 in the body 120 and the temperature of the refrigerant injected into the hollow interior 111 of the probe 110 The second temperature sensor 124 measures the temperature of the refrigerant circulating through the refrigerant circulation path. Here, the measured temperature is transferred to the gas supply device 200.

The body 120 is provided with a handle 121 provided with a trigger 122 to pull the trigger 122 with a finger while holding the handle 121 by hand. Here, the trigger 122 serves as a switch for controlling the operation of the valve unit 130. It should be noted that driving means for opening and closing the first valve 130a and the second valve 130b are not shown because known driving means used for valve driving can be employed.

The gas supply device 200 includes a user interface 121 for providing a user interface (UI) environment for inputting various setting values including a single injection amount of carbon dioxide, a temperature of the refrigerant, and a circulation time of the refrigerant, The carbon dioxide gas reservoir 240 is connected to the first valve 130a and the carbon dioxide stored in the carbon dioxide reservoir 240 is supplied to the carbon dioxide gas supply unit 230 And is connected to the second valve 130b so that the refrigerant is pressurized and supplied to the refrigerant pipe 114b by the intermittent movement of the second valve 130b and connected to the hollow inside 111 of the probe 110, A coolant circulation unit 220 for re-cooling and pressurizing the refrigerant recovered by returning the refrigerant refluxed through the inside 111, a trigger 122 provided in the hand gun 100, a first valve 130a , 130b and the first and second temperature sensors 123, 124 A controller 210 for controlling the first valve 130a to supply carbon dioxide by a preset amount and then controlling the second valve 130b to circulate the refrigerant for a preset time each time the trigger 122 is connected, ).

Here, a predetermined amount of carbon dioxide injected once every time the trigger is pulled and a predetermined time for circulating the refrigerant one time are set by the user interface 121. [

In the embodiment of the present invention configured as described above, when the probe 110 is inserted into the subcutaneous fat 2 through the skin 1 and then the trigger 122 is pulled, the carbonic acid gas supply unit 230 is activated, The valve 130a is opened so that carbon dioxide is injected into the subcutaneous fat 1 through the gas pipe 114a and the needle 112. [

Next, the first valve 130a is closed and the carbon dioxide supply operation of the carbonic acid gas supply unit 230 is stopped. Thereafter, the refrigerant circulation unit 220 is operated and the second valve 130b is opened, The circulation of the refrigerant circulating in the refrigerant circulation unit 220 along the reflux path through the hollow interior 111 after being injected into the hollow interior 111 of the probe 110 through the inlet 114b is performed for the predetermined time do.

At this time, the refrigerant circulating unit 220 re-supplies the refrigerant to be returned to the refrigerant pipe 114b by re-cooling the refrigerant to be returned, so that even if the end of the probe 110 is heated by the subcutaneous fat 2, 2) can be cooled. Here, the refrigerant may be a gas phase or a liquid liquid.

According to the embodiment of the present invention, the tip end of the coolant pipe 114b for spraying the coolant is close to the end of the hollow interior 111 of the probe 110 and inserted into the subcutaneous fat 2 at the pro 110 And an inner protrusion 113 is formed on the inner peripheral surface of the portion. Accordingly, the refrigerant ejected from the closed end of the hollow interior 111 hits against the inner protrusion 113 while being refluxed toward the main body 120 through the hollow interior 111, so that the heat exchange at the end Heat exchange between the end portion and the refrigerant) is actively performed. As a result, the portion close to the end portion of the probe 110 is intensively cooled, and the amount of heat exchange in the skin 1 is reduced to prevent the skin 1 from being damaged. The refrigerant circulation pipe between the hand gun 100 and the gas supply device 200 is insulated by the heat insulating material in the section where the refrigerant flows in the body 120 of the hand gun 100 to prevent heat loss.

The control unit 210 receives the temperature of the refrigerant supplied to the hollow interior 111 through the refrigerant pipe 114b of the probe 110 and the temperature of the refrigerant circulated through the hollow interior 111, The refrigerant circulation unit 220 is controlled so as to lower the temperature of the supplied refrigerant and to increase the temperature of the supplied refrigerant if it is greater than a predetermined error. Accordingly, the temperature difference between the supplied refrigerant and the return water refrigerant is maintained and adjusted to a predetermined error value. That is, if the circulating flow rate (amount circulated per unit time) of the refrigerant is constant, even if there is a part of the loss in the skin 1, the loss is minimized so that the heat absorbed in the subcutaneous fat 2 is absorbed by the temperature difference between the supply refrigerant and the return water refrigerant Can be approximated by proportional. Accordingly, the amount of heat absorbed in the subcutaneous fat 2 can be kept constant by adjusting the temperature of the supplied refrigerant according to the temperature difference.

At this time, the temperature of the supplied refrigerant is higher than the clinically obtainable lower limit cooling temperature to prevent damage to the skin (1) tissue, and is lower than the clinically obtainable upper limit temperature Maintain the range.

As such, the CO2 injection and subcutaneous fat cooling operations are repeated each time the trigger 122 is pulled.

Meanwhile, the present invention can be configured to cool the subcutaneous fat while injecting carbon dioxide into the subcutaneous fat when the trigger 122 is pulled. The control unit 210 of the gas supply apparatus 200 simultaneously activates the carbonic acid gas supply unit 230 and the coolant circulation unit 220 when the trigger 122 is pulled, 130a and the second valve 130b are simultaneously opened to inject carbon dioxide into the subcutaneous fat while circulating the coolant to cool the subcutaneous fat. At this time, the amount of carbon dioxide injected every time the trigger 122 is pulled is set to the predetermined amount, and since the time for circulating the refrigerant is the predetermined time, the preset amount of time Of carbon dioxide is uniformly injected.

On the other hand, a procedure for injecting carbon dioxide while changing the portion of the subcutaneous fat into which the probe 110 is inserted and injecting carbon dioxide once for each changed portion, and then cooling the subcutaneous fat may also be employed. For this purpose, the trigger (122) is provided in two so that when one trigger is pulled, carbon dioxide is injected and, if another trigger is pulled, the coolant is circulated by circulating.

On the other hand, instead of injecting a predetermined amount of carbon dioxide every time the trigger is pulled, the first valve 130a is controlled to be open while any one of the triggers is pulled to continuously inject carbon dioxide until the trigger is released, While the second trigger 130b is being pulled, the second valve 130b may be controlled to be opened so as to be continuously cooled until the trigger is released. In this case, it is advantageous for the operator to appropriately adjust the injection amount of carbon dioxide and the cooling time according to the thickness of subcutaneous fat.

In the description of the embodiment of the present invention, carbon dioxide is injected through the gas pipe 114a. However, the present invention is not limited to injecting carbon dioxide, air, and / or drugs (for example, HPL drug or mesotherapy drug) In this case, the carbon dioxide gas supply part 230 of the gas supply device 200 is configured to supply carbon dioxide, air and drugs sequentially, or inject a selected one through the user interface.

FIG. 4 is a schematic view of a local fat fusing apparatus using a high-pressure carbonic acid gas and a coolant according to a second embodiment of the present invention. FIG. 5 is a cross-sectional view of the hand gun 100, Fig.

According to the second embodiment of the present invention, since the carbon dioxide stored in the carbon dioxide gas reservoir 240 is used as the refrigerant in the refrigerant circulation unit 220, the gas supplied to the subcutaneous fat and the probe 110 are used as carbon dioxide. The hand gun 100 is configured to selectively supply carbon dioxide and a coolant (carbon dioxide to be cooled and supplied) to the hollow interior 111 of the probe 110 through an injection tube 114 constituted by a single tube.

The injection tube 114 inserted into the hollow interior 111 of the probe 110 is composed of a single tube and the end is inserted into the end of the hollow interior 111 of the probe 110. That is, the needle 112 provided at the end of the probe 110 is in communication with the hollow interior 111 of the probe 110 and is not directly connected to the injection tube 114, Are spaced apart.

The valve unit 130 accommodated in the body 120 is composed of a switching valve 130c and an intermittent valve 130d.

The switching valve 130c is connected to the gas supply device 200 and includes a pipe for supplying carbon dioxide for subcutaneous fat injection, a pipe connected to the refrigerant circulation part 220 and supplied with carbon dioxide (coolant) for cooling the probe end, And a pipe connected to a single injection tube 114 is connected to select one of carbon dioxide for injecting subcutaneous fat and carbon dioxide for a coolant and inject it into the injection tube 114 selectively.

The intermittent valve 130d is connected to a pipe connected to the hollow interior 111 of the probe 110 and a pipe for returning the carbon dioxide for the refrigerant to the gas supply device 200 to control the circulation path of the refrigerant.

The carbon dioxide injection operation and the cooling operation, which are performed by pulling the trigger 122, are as follows.

When the carbon dioxide is injected into subcutaneous fat, carbon dioxide for subcutaneous fat injection is injected into the injection tube 114 by controlling the switching valve 130c in a state where the regulator valve 130d is closed and the reflux path is closed. Accordingly, the pressure of the hollow interior 111 of the probe 110 gradually increases to rise to a predetermined pressure (a pressure enough to inject into the subcutaneous fat), so that carbon dioxide is injected into the subcutaneous fat through the needle 112.

When cooling the end portion of the probe 110, the shutoff valve 130d is opened to control the switching valve 130c in a state in which the reflux path is opened to inject the carbon dioxide for the refrigerant into the injection pipe 114. [ The carbon dioxide injected into the hollow interior 111 of the probe 110 is returned to the gas supply device 200 through the reflux path to cool the end of the probe 110. At this time, since the reflux path is opened and the pressure of the hollow interior 111 of the probe 110 is low, carbon dioxide is not injected into the subcutaneous fat through the needle 112 or is slightly injected, little.

According to the second embodiment of the present invention configured as described above, since the injection tube 114 is constituted by a single tube, the probe 110 is made as thin as possible, and the incision 3 opened in the skin 1 is made small .

FIG. 6 is a configuration diagram of a local fat fusing apparatus using a high-pressure carbon dioxide gas and a coolant according to a third embodiment of the present invention, and is a view showing a hand gun 100 in a sectional view.

FIG. 7 is an enlarged view of the valve unit 130 shown in FIG. 6, and shows a state change stepwise according to the change of the position of the plunger 135 by the valve driving unit 140.

According to the third embodiment of the present invention, the valve unit 130 is constituted by one cylinder instead of the switching valve 130c and the intermittent valve 130d.

The valve 131 is inserted into the open end of the cylinder 131 and is reciprocated by the valve driving unit 140 so as to be inserted into the inside of the cylinder 131 And a plunger 135 connected to the first piston 132 and the second piston 133 arranged.

The cylinder 131 is connected to the carbonic acid gas supply unit 230 and has a carbonic acid gas injection port 131a for injecting carbon dioxide into the cylinder 131. The cylinder 131 is connected to the injection pipe 114 inserted into the hollow of the probe 110, A refrigerant inlet port 131c connected to the refrigerant circulation unit 220 and injecting the refrigerant into the cylinder 131, a refrigerant inlet port 131d connected to the hollow interior 111 of the probe 110, A coolant discharge port 131e connected to the coolant circulation unit 220 is connected to the coolant circulation unit 220 of the gas supply device 200 so as to communicate with the inside thereof.

At this time, the refrigerant return port 131d and the refrigerant discharge port 131e are provided close to the other closed end of the cylinder 131. When the first piston 132 reaches the other closed end of the cylinder 131, , And the first piston 132 is moved toward one end opened at the other closed end of the cylinder 131 to be communicated with each other.

The carbonic acid gas injection port 131a, the discharge port 131b and the coolant injection port 131c are connected to the carbonic acid gas inlet 131a and the discharge port 131b from the one end of the cylinder 131 where the plunger 135 is inserted, And the coolant inlet port 131c closest to the closed end of the cylinder 131 are spaced apart from the coolant inlet port 131d and the coolant outlet port 131e do. Here, the meaning of the interval and spacing refers to the distance in the longitudinal direction of the cylinder 131, that is, the distance and the spacing on the reciprocating motion line of the plunger and the first and second pistons.

The plunger 135 is inserted into the open inlet side of the cylinder 131 so as to reciprocate, and at least a portion of the outer end is exposed to the outside of the cylinder 121 in a state of being inserted at the maximum depth, And the end is gripped by the valve driving part 140 to reciprocate. It is preferable that the maximum insertion depth of the plunger 135 be at least before the end of the plunger 135 inserted into the cylinder 131 reaches at least the discharge port 131b.

The inner end of the plunger 135 inserted into the cylinder 131 is provided with an insertion port 135a which is formed along the reciprocating motion line of the plunger 135 toward the outer end and formed into a deep groove shape with the inlet 135b narrowed .

The other end of the piston rod 134 having the first piston 132 fixed at one end and the second piston 133 fixed at the middle is inserted into the insertion port 135a. The other end of the piston rod 135 is formed with a free end 134a which is accommodated in the insertion port 135a and has a larger diameter than the inlet 135b. The free end 134a is inserted into the insertion port 135a and is freely reciprocatable within a predetermined section within the depth of the insertion port 135a. The free end 134a is caught by the narrowed entrance 135b and exits from the insertion port 135a No. That is, the plunger 135 can move relative to the first piston 132 and the second piston 132 fixed to the piston rod 134, and conversely, the first piston 132 fixed to the piston rod 134, (132) and the second piston (132) are capable of relative movement with respect to the plunger (135).

The distance between the first piston 132 and the second piston 133 is set such that the first piston 132 reaches the closed end of the cylinder 131 and the refrigerant return port 131d and the refrigerant discharge port 131e are closed The second piston 133 closes the coolant inlet port 131c and the discharge port 131b communicates with the space between the second piston 133 and the plunger 135. [ The interval is determined.

When the first piston 132 is caused to reach the closed end of the cylinder 131 in a state in which the distance between the second piston 133 and the plunger 135 can be maximized, The plunger 135 closes the carbonic acid gas inlet 131a and the first piston 132 is spaced apart from the closed end of the cylinder so that the coolant return port 131d and the coolant discharge port 131e are communicated with each other The carbonic acid gas inlet 131a is communicated with the second piston 133 and the plunger 133 when the coolant inlet port 131c and the discharge port 131b are communicated with each other through the space between the first piston 132 and the second piston 133, (135). ≪ / RTI >

The valve driving unit 140 may adopt a known technique of reciprocating the plunger. As illustrated in the figure, the block 141 holding the outer end of the plunger 135 is connected to the plunger 135 The screw 143 is screwed to the rotatable screw 143 provided along the reciprocating motion direction of the screw 143 and reciprocates as the screw 143 rotates forward and backward by the motor 144.

As described above, the valve unit 130 coupled to the valve driving unit 140 has three operating states by reciprocating the plunger 135 as shown in FIG.

7A is a state in which the plunger 135 is pulled out to the maximum extent within the allowance of the cylinder 131 and the first piston 132 and the second piston 133 are also pulled toward the inlet of the cylinder The first piston 132 is separated from the closing end of the cylinder so that the refrigerant return port 131d and the refrigerant discharge port 131e communicate with each other and the refrigerant inlet port 131c and the discharge port 131b are communicated with the first piston 132, Through the space between the second pistons (133). Thus, the circulation path of the refrigerant is opened. Accordingly, the end of the probe 110 can be cooled by circulating the refrigerant.

In addition, since the space between the second piston 133 and the plunger 135 communicates only with the carbonic acid gas inlet 131a, the carbon dioxide to be injected into the subcutaneous fat is pressurized and filled in the space. That is, the space between the second piston 133 and the plunger 135 compressively stores carbon dioxide.

When the plunger 135 is pushed into the cylinder 131 in the state of Fig. 7 (a), the pressure of the carbon dioxide filled in the space between the second piston 133 and the plunger 135 causes the second piston 133 to move The state of FIG. 7 (b) in which the first piston 132 reaches the end where the cylinder is closed becomes the state where the pressure is applied toward the closed end.

7 (b), the refrigerant return port 131d and the refrigerant discharge port 131e are closed by the first piston 132, the refrigerant inlet port 131c is closed by the second piston 132, The carbonic acid gas inlet 131a is closed by the plunger 135. [ On the other hand, the discharge port 131b communicates with the space between the plunger 135 and the second piston 133 filled with carbon dioxide by pressurization. Accordingly, the pressurized carbon dioxide starts to flow into the injection tube 114 through the discharge port 131b.

When the plunger 135 is further pushed into the cylinder 131 in the state of Fig. 7 (b), since the first piston 132 is in contact with the closed end of the cylinder 131, 7 (c) in which the carbon dioxide filled in the space between the second piston 133 and the plunger 135 is injected into the injection tube 114 through the discharge port 131b with a stronger pressure as the piston 133 moves toward the piston 133, .

Accordingly, carbon dioxide can be injected into the subcutaneous fat through the needle 112 by the pressure of the carbon dioxide injected into the injection tube 114. That is, in the carbonic acid gas supply unit 230, carbon dioxide is injected into the valve unit 130 at a pressure capable of being injected into the subcutaneous fat, even if carbon dioxide is not supplied to the subcutaneous fat.

7 (b), the free end 134a of the piston rod 134 is inserted into the insertion port 135a, and the plunger 135 is pulled out of the cylinder 131. At this time, The first piston 132 and the second piston 133 are also pulled and switched to the state shown in Figure 7 (a). At this time, since the carbon dioxide filled in the space between the second piston 133 and the plunger 135 releases the pressurization in the state where the plunger 135 is pressed by the plunger 135, do.

As described above, by changing the state of the three states shown in Fig. 7 at an appropriate time, operations for subcutaneous fat injection of carbon dioxide and probe cooling can be performed. 7 (b) and 7 (c), when the trigger is pulled at an initial point in time when the pressurized supply of the carbon dioxide is maintained and the valve portion 130 is in the state shown in Fig. 7 (a) And then carbon dioxide is injected into the subcutaneous fat. Thereafter, the system is sequentially switched to the state shown in Figs. 7 (b) and 7 (a) to circulate the refrigerant for the preset time period and to stop the circulation of the refrigerant .

An O-ring is provided in the first piston 132 and the second piston 133 to maintain airtightness with the inner circumferential surface of the cylinder 131 and an O-ring is provided on the opening side of the cylinder 131, And an O-ring is also provided at the inlet 135b of the insertion port 135a to maintain airtightness with the outer circumferential surface of the piston rod 134. [ The outer diameter of the free end 134a of the piston rod 134 is made smaller than the inner diameter of the insertion port 135a to reduce the resistance when the free end 134a reciprocates in the insertion port 135a.

The pressure of the carbon dioxide supplied to the carbonic acid gas supply unit 230 is relatively higher than the pressure of the refrigerant supplied to the refrigerant circulation unit 220. In the case of the refrigerant, .

A check valve for preventing backflow is provided in the carbonic acid gas inlet 131a in the cylinder 131 or a hermetic sealing material provided around the inlet so as to be closed when facing the reciprocating plunger 135 It is good to do.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, . ≪ / RTI > Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

1: skin 2: subcutaneous fat 3: incision window
100: Hand Gun
110: probe 111: hollow interior 112: needle
113: inner projection 114: injection tube 114a: gas pipe
114b: refrigerant tube
120: body 121: handle 122: trigger
123: first temperature sensor 124: second temperature sensor
130: valve portion 130a: first valve 130b: second valve
130c: a switching valve 130d: an intermittent valve
131: cylinder 131a: carbonic acid gas inlet 131b:
131c: Refrigerant inlet port 131d: Refrigerant inlet port 131e: Refrigerant outlet port
132: first piston 133: second piston 134: piston rod
134a: free end 135: plunger 135a:
135b: entrance
140:
200: gas supply device
210: control unit 211: user interface
220: coolant circulation unit 230: carbon dioxide gas supply unit
240: Carbon dioxide gas reservoir

Claims (6)

A gas supply device 200 that pressurizes carbon dioxide to supply it to the hand gun 100 and circulates the coolant to the hand gun 100; And
The injection tube 114 is inserted into the hollow interior 111 of the probe 110 provided with the needle 112 at the end to be inserted into the subcutaneous fat 2 through the skin 1 to inject carbon dioxide into the injection tube 114, And injected into the subcutaneous fat 2 via the needle 112. The refrigerant is circulated through the injection tube 114 and then returned through the hollow interior 111 so that the end of the probe 110 is circulated through the refrigerant circulation A valve unit 130 and a trigger 122 for cooling and circulating the coolant are provided so as to control the valve unit 130 every time the trigger 122 is pulled, A hand gun (100) for injecting and circulating the refrigerant for a preset time;
Wherein the high-pressure carbonic acid gas and the refrigerant are mixed. The method according to claim 1,
The injection tube 114 includes a gas pipe 114a inserted into the hollow interior 111 and connected to the needle 112 and a refrigerant pipe 114b inserted into the hollow interior 111 to reach the end of the probe 110 And the carbon dioxide is injected into the subcutaneous fat 2 through the gas pipe 114a and the needle 112 so that the refrigerant is circulated through the refrigerant pipe 114b and the hollow interior 111. [ Local fat fusing device using gas and refrigerant. 3. The method of claim 2,
Wherein the hand gun (100) supplies carbon dioxide by a preset amount every time the trigger (122) is pulled, and at the same time circulates the coolant for a preset time. The method according to claim 1,
The injection tube 114 is composed of a single tube leading to the end of the probe 110,
The refrigerant is carbon dioxide,
The valve portion 130
An intermittent valve 130d for interrupting a refrigerant return path through the hollow interior 111 of the probe 110; And
A switching valve 130c for selecting any one of carbon dioxide and refrigerant to be injected into the injection tube 114;
The control valve 130d is closed when the carbon dioxide is injected into the injection pipe 114 and the control valve 130d is closed when the refrigerant is injected into the injection pipe 114. [ Characterized in that the high-pressure carbonic acid gas and the refrigerant are used in an open operation. 5. The method of claim 4,
The valve portion 130
The other end of the piston rod 134 having the first piston 132 fixed at one end and the second piston 133 fixed at the middle is inserted into the end of the plunger 135, And the plunger 135 is inserted into the inlet of the cylinder 131 so that the first piston 132 and the second piston 133 are disposed inside the cylinder 131,
A carbonic acid gas injection port 131a for injecting carbon dioxide into the cylinder 131, a discharge port 131b connected to the injection pipe 114 and a refrigerant inlet port 131c for injecting the refrigerant into the cylinder 131, A refrigerant return port 131d connected to the hollow interior 111 of the probe 110 and a refrigerant return port 131d connected to the closed end of the cylinder 131 opposite to the inlet of the cylinder 131, A refrigerant discharge port 131e connected to the gas supply device 200 for recycling to the compressor 200 is formed,
When the refrigerant is circulated, the plunger 135 is pulled out of the cylinder 131 so that the first piston 132 and the second piston 133 are pulled out, and the refrigerant is discharged through the space between the other end closed and the first piston 132, The refrigerant inlet port 131c and the discharge port 131b are communicated with each other through the space between the first piston 132 and the second piston 133 and the refrigerant discharge port 131c is communicated with the discharge port 131b through the space between the first piston 132 and the second piston 133, , The carbonic acid gas inlet 131a communicates with the space between the second piston 133 and the plunger 135 to compress and store the carbon dioxide,
When the carbon dioxide is injected into the subcutaneous fat, the plunger 135 is pushed into the cylinder 131 so that the first piston 132 reaches the closed end of the cylinder 131 to cool the refrigerant return port 131d and the refrigerant discharge port The space between the second piston 133 and the plunger 135 is communicated with the discharge port 131b and the plunger 135a is connected to the plunger 135. The second piston 133 closes the refrigerant injection port 131c, The carbonic acid gas injection port 131a is closed by the valve 135 and then only the plunger 135 is pushed so that the carbon dioxide is pressurized and discharged to the discharge port 131b. Device. The method according to any one of claims 1 to 5,
The probe 110 includes an inner protrusion 114 that locally presses the outer circumferential surface of the portion to be inserted into the subcutaneous fat 2 and protrudes to the inner circumferential surface,
The hand gun 100 includes temperature sensors 123 and 124 for sensing the difference between the temperature of the refrigerant injected into the injection tube 114 of the probe 110 and the temperature of the refrigerant circulated through the hollow interior 111 If the temperature difference is less than a preset error, the temperature of the supplied refrigerant is lowered. If the temperature difference is larger than a preset error, the temperature of the supplied refrigerant is adjusted to maintain a predetermined error by increasing the temperature of the supplied refrigerant. Wherein the high-pressure carbonic acid gas and the high-pressure carbonic acid gas are maintained within a predetermined range.

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