WO2022015067A1 - 의료용 냉각 시스템 및 이를 이용하는 의료용 냉각 장치 - Google Patents
의료용 냉각 시스템 및 이를 이용하는 의료용 냉각 장치 Download PDFInfo
- Publication number
- WO2022015067A1 WO2022015067A1 PCT/KR2021/009073 KR2021009073W WO2022015067A1 WO 2022015067 A1 WO2022015067 A1 WO 2022015067A1 KR 2021009073 W KR2021009073 W KR 2021009073W WO 2022015067 A1 WO2022015067 A1 WO 2022015067A1
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- Prior art keywords
- coolant
- temperature
- module
- cooling
- grip
- Prior art date
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Images
Classifications
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- F16L—PIPES; JOINTS OR FITTINGS FOR PIPES; SUPPORTS FOR PIPES, CABLES OR PROTECTIVE TUBING; MEANS FOR THERMAL INSULATION IN GENERAL
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- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
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- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
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- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
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- A61F7/00—Heating or cooling appliances for medical or therapeutic treatment of the human body
- A61F2007/0087—Hand-held applicators
Definitions
- the present invention relates to a cooling system for performing cooling and a cooling device using the same, and more particularly, to a cooling device using a filter fixing module for easily detaching and safely cooling a target, and a cooling method thereof.
- a conventional cooling device for skin treatment particularly a cooling device using a method of cooling the skin by spraying a coolant on the skin
- a coolant supply source which is used by connecting a coolant tank with a cooling device through a hose or using a coolant cartridge. It has been installed and used in a cooling device.
- the existing cooling device was not compatible with both the hose and the coolant cartridge connected to the coolant tank, and was used individually as a coolant tank cooling device and a coolant cartridge cooling device.
- a cooling device for skin treatment may inevitably have a safety problem in that the treatment is performed on the skin.
- impurities contained in the coolant may be transferred to a target area of the skin, thereby causing an infection of the skin.
- An object of the present invention is to provide a filter fixing module for accommodating a filter mounted on a cooling device to filter impurities from a coolant.
- One problem to be solved by the present invention is to provide a cooling device in which a filter fixing module is mounted and separated.
- the filter fixing module mounted on the handpiece cooling device having a coupling portion to be coupled to the coolant supply unit is formed on a support surface formed in a flat plate shape in the first direction and an edge of the support surface, and the support a body having a receiving surface protruding in a second direction with respect to the surface to prevent separation of the filter accommodated in the support surface, wherein the first direction and the second direction are different; and a grip portion connected to the body, wherein the grip portion may include a first grip member and a second grip member extending in a direction opposite to a direction in which the receiving surface extends with respect to the body.
- a cooling device for cooling by spraying a coolant flowing in from a coolant supply unit accommodating coolant to a target area, comprising: a valve for controlling a flow of coolant; a nozzle for spraying a coolant to the target area; a pipe providing a passage for moving the fluid so that the coolant supplied from the coolant supply unit passes through the valve and is sprayed through the nozzle;
- the valve a body for accommodating the nozzle and the tube therein; and a first screw thread coupled to the first housing, a second screw thread coupled to the coolant supply unit, and a coolant moving hole formed to introduce the coolant supplied from the coolant supply unit into the pipe, and between the coolant supply unit and the pipe.
- a filter fixing module comprising: a support surface formed in a plate shape; a body formed on an edge of the support surface and having a receiving surface protruding in a first direction with respect to the support surface; and a grip part connected to the body; includes a first grip member and a second grip member extending in opposite sides to the direction in which the receiving surface protrudes with respect to the body, and the filter fixing module is installed in a state in which the filter is disposed on the receiving surface of the coupling member.
- the filter may be disposed between the support surface and the coolant moving hole so that impurities in the coolant introduced into the coolant moving hole by the filter are filtered out.
- the filter fixing module can be easily mounted and detached from the cooling device through the structure of the filter fixing module protruding to the outside of the cooling device.
- a fluid passage through which the coolant can move is formed, which may cause inconvenience to users due to the expansion of the coolant.
- FIG. 2 to 3 are views showing the cooling system 10 according to an embodiment of the present specification. Specifically, FIG. 2 is a diagram illustrating the cooling system 10 using a cartridge as the coolant supply unit 4000 , and FIG. 3 is a diagram illustrating the cooling system 10 using a coolant tank as the coolant supply unit 4000 .
- FIG 4 is a view showing the configuration of the cooling device 1000 and the filter fixing module 2000 according to an embodiment of the present specification.
- FIG 5 is a view showing a process of cooling the target through the cooling system 10 according to an embodiment of the present specification.
- FIG. 6 is a view showing an internal structure of the cooling device 1000 according to an embodiment of the present specification.
- FIG. 7 is a diagram illustrating a coolant temperature controller 1200 according to an embodiment of the present specification.
- FIG. 8 is a diagram illustrating a sensor module 1400 according to an embodiment of the present specification.
- FIG 9 is a view showing the internal structure of the cooling device 1000 to which the filter fixing module 2000 is mounted according to an embodiment of the present specification.
- FIG 10 is an exploded view of the cooling device 1000 on which the filter fixing module 2000 is mounted according to an embodiment of the present specification.
- FIG 11 is a perspective view of a coupling member 1840 to which the filter fixing module 2000 according to an embodiment of the present specification is mounted.
- FIG. 12 is a view showing an aspect in which the filter fixing module 2000 and the coupling member 1840 are coupled according to an embodiment of the present specification.
- FIG. 13 is a view illustrating an aspect in which the coolant supply unit 4000 is screwed to the coupling member 1840 and drilled by the perforation member 2200 of the filter fixing module 2000 according to an embodiment of the present specification.
- FIG. 14 is an exploded view of the filter fixing module 2000 according to an embodiment of the present specification.
- 15 is a view showing the body 2100 and the grip portion 2300 of the filter fixing module 2000 according to an embodiment of the present specification.
- 16 is a view illustrating a relationship between the body 2100 and the first sealing member 2410 of the filter fixing module 2000 according to an embodiment of the present specification.
- 17 is a view illustrating an aspect in which the coolant supply unit 4000 is separated from the coupling member 1840 and the filter fixing module 2000 according to an embodiment of the present specification.
- FIG. 18 is a view illustrating an aspect in which the filter fixing module 2000 is separated from the coupling member 1840 according to an embodiment of the present specification.
- 19 is a flowchart related to the operation of the control module 1700 for determining whether the sensor module 1400 operates normally according to an embodiment of the present specification.
- 20 is a diagram illustrating an aspect of measuring first temperature information and second temperature information to determine whether the sensor module 1400 operates normally according to an embodiment of the present specification.
- 21 is a diagram illustrating an aspect in which the control module 1700 calculates a difference between first temperature information and second temperature information in order to determine whether the sensor module 1400 operates normally according to an embodiment of the present specification.
- 22 is a diagram illustrating an aspect of measuring the temperature information of a target using at least one of the first temperature sensor 1410 and the second temperature sensor 1420 according to an embodiment of the present specification.
- control module 1700 is a flowchart related to the operation of the control module 1700 for obtaining an input for initiating a cooling operation according to an embodiment of the present specification.
- 24 is a diagram illustrating a plurality of input modules 1500 according to an embodiment of the present specification.
- 25 is a diagram illustrating an aspect of acquiring information related to a cooling condition through the input module 1510 according to an embodiment of the present specification.
- 26 is a flowchart illustrating a method in which the control module 1700 controls the coolant flow controller 1100 and/or the coolant temperature controller 1200 according to an embodiment of the present specification.
- FIG. 27 is a flowchart illustrating a method in which the control module 1700 disclosed herein outputs a measured temperature of a target through the output module 1600 .
- 28 is a diagram illustrating an output of the temperature of the target measured through the output module 1600 disclosed herein.
- a specific process sequence may be performed different from the described sequence.
- two processes described in succession may be performed substantially simultaneously, or may be performed in an order opposite to the order described.
- the filter fixing module mounted on the handpiece cooling device having a coupling portion to be coupled to the coolant supply unit is formed on a support surface formed in a plate shape and an edge of the support surface, and based on the support surface a body having a receiving surface protruding in a first direction to prevent separation of the filter accommodated in the support surface, and a grip portion connected to the body, wherein the grip portion is opposite to the direction in which the receiving surface protrudes with respect to the body It may include a first grip member and a second grip member extending to the.
- a perforation member having a body having a shape protruding from the support surface on the same side as the first grip member and the second grip member with respect to the support surface
- the perforation member has a hollow hole so that the coolant flowing in from the coolant supply part moves when the coolant supply part is coupled to the coupling part, the hollow hole having a first end for accommodating the coolant flowing in from the coolant supply part, the support surface;
- a filter holding module may be provided which is adjacent and includes a second end for outputting coolant to the handpiece cooling device.
- the first grip member includes a 1-1 region extending in a second direction and a 2-1 region extending in a third direction having a predetermined angle with the second direction. is provided in the shape of a bent flat plate, wherein the second grip member includes a first-first area extending substantially parallel to the second direction and a second-second area extending in a fourth direction having a predetermined angle with the second direction It is provided in a bent flat plate shape including two regions, and the 1-1 region of the first grip member and the 1-2 region of the second grip member are spaced apart from each other by a first distance and substantially parallel, A maximum separation distance between the 2-1 region of the first grip member and the 2-2 region of the second grip member may be greater than the first distance, and a filter fixing module may be provided.
- the separation distance from the support surface of the 2-1 region of the first grip member and the 2-2 region of the second grip member is the first of the perforation member.
- a filter holding module may be provided, which is large compared to the separation distance from the support surface of the end.
- the body and the perforation member have an integral shape, and in the center of the support surface connected to the second end of the perforation member, the coolant introduced from the second end of the perforation member A connection hole configured to output to the filter side accommodated by the receiving surface is formed, a filter fixing module may be provided.
- the filter fixing module further includes a first sealing member having an outer diameter smaller than the outer diameter of the receiving surface so that at least a partial region is accommodated in the receiving surface, the first sealing member includes a hollow hole that receives the coolant passing through the connection hole of the support surface and forms a passage to output the coolant to the handpiece cooling device, and the coolant flows out through the contact surface between the support surface and the first sealing member
- a filter fixing module may be provided, which reduces leakage.
- the length in the first direction of the receiving surface protruding from the support surface is smaller than the thickness of the first sealing member, when the first sealing member is accommodated in the receiving surface
- At least a partial region of the first sealing member may be provided with a filter fixing module that protrudes outwardly from the receiving surface.
- the filter fixing module has a through hole, and the coolant to be provided from the coolant supply unit to the hollow hole of the punching member is a second second that reduces leakage to the outer surface of the punching member Further comprising a sealing member, the inner diameter of the second sealing member defined by the through hole is larger than the outer diameter of the perforation member, the filter fixing module may be provided.
- the length of the body of the perforation member is longer than the thickness of the second sealing member, and when the perforation member is accommodated in the through hole of the second sealing member, the first of the perforation member A filter fixing module having an end protruding to the outside of the second sealing member may be provided.
- the first sealing member may be made of a plastic material or a rubber material, and more specifically, Teflon or Nylon 6 (Nylon 6-6), the filter fixing A module may be provided.
- the second sealing member may be made of a plastic material or a rubber material, and more specifically, Teflon or Nylon 6 (Nylon 6-6), the filter fixing module can be provided.
- the filter is configured to be disposed between the first sealing member and the second sealing member, a filter fixing module may be provided.
- the filter is configured to be disposed between the first sealing member and the support surface, a filter fixing module may be provided.
- the filter fixing module may use an adhesive to fix the first sealing member.
- the second sealing member may not be included in the filter fixing module but may be provided by being configured in the coolant supply unit, wherein the second sealing member has a shape that is mechanically coupled to the coolant supply unit.
- it may be provided with a coolant supply unit through an adhesive.
- a cooling device for cooling by spraying a coolant flowing in from a coolant supply unit accommodating coolant to a target area, comprising: a valve for controlling a flow of coolant; a nozzle for spraying a coolant to the target area; a pipe providing a passage for moving the fluid so that the coolant supplied from the coolant supply unit passes through the valve and is sprayed through the nozzle;
- the valve a body for accommodating the nozzle and the tube therein; and a first screw thread coupled to the first housing, a second screw thread coupled to the coolant supply unit, and a coolant moving hole formed to introduce the coolant supplied from the coolant supply unit into the pipe, and between the coolant supply unit and the pipe.
- a filter fixing module comprising: a support surface formed in a plate shape; a body formed on an edge of the support surface and having a receiving surface protruding in a first direction with respect to the support surface; and a grip part connected to the body; includes a first grip member and a second grip member extending in opposite sides to the direction in which the receiving surface protrudes with respect to the body, and the filter fixing module is installed in a state in which the filter is disposed on the receiving surface of the coupling member.
- the filter When positioned in one area, the filter may be disposed between the support surface and the coolant movement hole so that impurities of the coolant introduced into the coolant movement hole by the filter are filtered out, a medical cooling device may be provided.
- the second screw thread includes at least two groove members, wherein the first grip member and the second grip member are fitted into the at least two groove members, respectively, so that the filter fixing module is connected to the coupling member can be connected to
- a force is applied in a direction in which the first grip member and the second grip member approach each other.
- the first grip member and the second grip member may be separated from the at least two groove members.
- connection part including the coupling member and the first housing is further included, wherein the first housing includes a first coupling part coupled to the coupling element formed on the outer surface of the main body and the It may further include a second coupling portion coupled to the first screw thread formed on the outer surface of the coupling member.
- the medical cooling device may further include a control module for controlling the opening and closing operation of the valve.
- the filter fixing module has a body protruding from the support surface on the same side as the first grip member and the second grip member with respect to the support surface, and the coolant a perforating member for perforating the coolant supply part when the supply part is coupled to the second screw thread, wherein the body has a hollow hole through which the coolant flowing in from the coolant supply part moves, and the hollow hole flows in from the coolant supply part
- a medical cooling device may be provided, comprising a first end for receiving a coolant, a second end adjacent to the support surface and for outputting coolant in the tube direction.
- the first grip member includes a 1-1 region extending in a second direction and a 2-1 region extending in a third direction having a predetermined angle with the second direction. is provided in the shape of a bent flat plate, wherein the second grip member includes a first-first area extending substantially parallel to the second direction and a second-second area extending in a fourth direction having a predetermined angle with the second direction It is provided in a bent flat plate shape including two regions, and the 1-1 region of the first grip member and the 1-2 region of the second grip member are spaced apart from each other by a first distance and substantially parallel, A maximum separation distance between the 2-1 region of the first grip member and the 2-2 region of the second grip member is greater than the first distance, and a medical cooling device may be provided.
- the separation distance from the support surface of the 2-1 region of the first grip member and the 2-2 region of the second grip member is the first of the perforation member.
- a medical cooling device may be provided, which is large compared to the distance from the support surface of the end.
- the body and the perforation member have an integral shape, and in the center of the support surface connected to the second end of the perforation member, the coolant introduced from the second end of the perforation member.
- a medical cooling device in which a connection hole configured to output to the side of the filter accommodated by the receiving surface is formed.
- the filter fixing module further includes a first sealing member having an outer diameter smaller than the outer diameter of the receiving surface so that at least a partial region is accommodated in the receiving surface, the first sealing member includes a hollow hole that receives the coolant passing through the connection hole of the support surface and forms a passage to output the coolant to the tube side, and the coolant leaks through the contact surface between the support surface and the first sealing member.
- a medical cooling device can be provided.
- the length in the first direction of the receiving surface protruding from the support surface is smaller than the thickness of the first sealing member, when the first sealing member is accommodated in the receiving surface At least a partial region of the first sealing member protrudes outwardly from the receiving surface to contact the coupling member, a medical cooling device may be provided.
- the filter fixing module has a through hole
- the coolant to be provided from the coolant supply unit to the hollow hole of the punching member is a second second that reduces leakage to the outer surface of the punching member
- the inner diameter of the second sealing member defined by the through hole of the second sealing member is larger than the outer diameter of the perforation member, the medical cooling device can be provided.
- the length of the body of the perforation member is longer than the thickness of the second sealing member, and when the perforation member is accommodated in the through hole of the second sealing member, the first end of the perforation member
- a medical cooling device may be provided that protrudes to the outside of the second sealing member and contacts the coolant outlet of the coolant supply unit.
- the first sealing member may be made of a plastic material or a rubber material, and more specifically, Teflon or Nylon 6 (Nylon 6-6), the filter fixing A module may be provided.
- the second sealing member may be made of a plastic material or a rubber material, and more specifically, Teflon or Nylon 6 (Nylon 6-6), the filter fixing module can be provided.
- the filter is configured to be disposed between the first sealing member and the second sealing member, a medical cooling device may be provided.
- the filter is configured to be disposed between the first sealing member and the support surface, a medical cooling device may be provided.
- the second thread includes at least two groove members, and at least a partial region of the 1-1 region of the first grip member is formed substantially parallel to the second direction.
- the present invention relates to a cooling system for performing cooling and a cooling device using the same, and more particularly, to a cooling device using a filter fixing module for easily detaching and safely cooling a target, and a cooling method thereof.
- the target can be cooled to a cooling state by using a cooling system for cosmetic or treatment on the target, and at this time, a cooling control method is used so that the target is not damaged due to overcooling.
- the target may mean a target to be cooled using a cooling system.
- the target may mean a skin cosmetic treatment target using cooling.
- the target is a point that can be removed by cooling a local area, a part of the body including warts, corns, acne scars, etc. may include
- the target may mean a target to be made into an anesthetic state or a pain-free state in order to receive a medical procedure.
- the target may refer to a part of the body including a nerve, such as a diseased eyeball, skin, or gums.
- Cooling refers to lowering the temperature of the target to be cooled by absorbing the thermal energy of the target to be cooled by applying cooling energy to the target to be cooled.
- the cooling energy is for expressing that heat escapes by cooling, and may be understood as a concept for expressing that the thermal energy is reduced.
- cooling may apply cooling energy to the target to be cooled in a manner of 'spraying' a coolant or air gas to the target to be cooled.
- cooling may apply cooling energy to a target to be cooled in such a way that the cooling medium is 'contacted' with the target to be cooled by applying cooling energy to the cooling medium.
- cooling the target through a non-contact method using a coolant is described as a main embodiment, but the technical spirit of the present specification is not limited thereto.
- the cooling system can also be used for therapeutic purposes such as relieving inflammation (eg, acne relief), relieving itching, pigmented lesions, vascular lesions, removing blemishes, and removing fat.
- the cooling system may cool the target to directly destroy at least a portion of the target.
- the cooling system provides cooling energy to the target through the target surface, and the provided cooling energy causes necrosis or death of tissues in the target. can do.
- the cooling system provides cooling energy by spraying a coolant on the target surface, and the temperature of the nerve at which the provided cooling energy is distributed under the target surface is the temperature at which the nerve is temporarily paralyzed or the temperature at which the nerve transmission is blocked. or less, so that the target can be anesthetized or pain-free.
- the cooling system may cool the target surface and the inside of the target to an appropriate temperature range to generate the anesthetic or analgesic state for a certain period of time.
- the cooling system 10 may include a cooling device 1000 , a filter fixing module 2000 , and a cradle 3000 .
- the cooling device 1000 may provide cooling energy to the target to cool the target. Specifically, as will be described later, the cooling device 1000 may cool the target by controlling the temperature of the coolant flowing through the flow path in the cooling device, thereby transferring the coolant having a target temperature to the target.
- the cooling device 1000 may be connected to the filter fixing module 2000 to filter impurities included in the coolant flowing in from the coolant supply unit 4000 . Also, the cooling device 1000 may cool the target with a coolant from which impurities have been filtered out. Through this, the cooling system 10 according to an embodiment of the present application can safely cool the target so that the target is not contaminated or infected.
- the cooling device 1000 may be mounted on the cradle 3000 after use or during use.
- the cooling device 1000 may be mounted on the cradle 3000 in an off state.
- the cooling device 1000 may be mounted on the cradle 3000 according to the user's convenience in a state in which power is supplied.
- the cooling device 1000 may be implemented as a portable device connected to a cartridge so that the user can easily carry it, or may be implemented in the form of a handpiece connected to a large device such as a coolant tank.
- the cooling device 1000 may be mounted on the cradle 3000 .
- the holder 3000 is designed to have a structure corresponding to the cooling device 1000 , so that the user can mount the cooling device 1000 on the holder 3000 during or after use of the cooling device 1000 .
- the cradle 3000 may include a temperature measurement area capable of measuring a temperature in order to determine whether the operation of the sensor module 1400 of the cooling device 1000 is normal, as will be described later, and the cooling device ( 1000) may have a shape to protect it.
- the temperature measurement area of the cradle 3000 will be described in detail with reference to FIG. 20 .
- the cradle 3000 may be omitted.
- the cooling system 10 may include a cooling device 1000 , a filter fixing module 2000 , a cradle 3000 , and a coolant supply unit 4000 .
- the coolant supply unit 4000 may be in the form of a cartridge. At this time, the cartridge is perforated by the perforation member of the filter fixing module, so that the coolant contained in the cartridge can be supplied to the cooling device side.
- the coolant supply unit 4000 may be configured as a cartridge including a plurality of materials or may be configured as a plurality of cartridges in order to deliver a material other than the coolant to the target site.
- the coolant supply unit 4000 may be in the form of a coolant tank.
- the coolant tank may be connected to a hose for supplying the coolant to the cooling device 1000 .
- the hose may supply the coolant accommodated in the coolant tank to the cooling device 1000 through screw coupling with the coupling member of the cooling device 1000 .
- the coolant supply unit 4000 is in the form of a coolant tank
- the coolant tank and hose may be interpreted as meanings of the coolant supply unit 4000 .
- the perforation member 2200 of the filter fixing module 2000 may be omitted.
- the coolant supply unit 4000 may include a plurality of materials in the coolant tank or may include a plurality of coolant tanks.
- FIG. 4 is a view showing the configuration of the cooling device 1000, the filter fixing module 2000, and the coolant supply unit 4000 according to an embodiment of the present specification.
- the cooling device 1000 includes a coolant flow control unit 1100 , a coolant temperature control unit 1200 , a nozzle unit 1300 , a sensor module 1400 , an input module 1500 , and an output module 1600 . ), a control module 1700 and a connection unit 1800 may be included.
- the coolant flow control unit 1100 may include a valve.
- the valve may perform a function of regulating the flow and flow rate of the coolant.
- the valve may perform a function of draining or blocking the coolant passing through the valve.
- the valve may perform a function of controlling the degree of outflow of the coolant passing through the valve.
- the valve according to an embodiment of the present application may be controlled according to a specific signal.
- the valve may be opened and closed in response to an electronic signal generated by the control module 1700 .
- the valve may be an electromagnetic valve (eg, a solenoid valve), but is not limited thereto.
- the valve according to an embodiment of the present application may be controlled according to a mechanical structure and movement of a fluid.
- the valve may open and close according to the pressure formed by the fluid moving along the flow path in the cooling device 1000 .
- the valve may be a hydraulic valve (eg, a pressure control valve), but is not limited thereto.
- the valve according to an embodiment of the present application may be controlled according to a user's input.
- the valve may be placed in an open state or in a closed state by the user.
- the valve may be a manual valve (eg, a globe valve), but is not limited thereto.
- the valve included in the coolant flow control unit 1100 may be located between the inlet (or referred to as an inlet) of the cooling device 1000 and the nozzle unit 1300 .
- the coolant flow control unit 1100 may control the amount of coolant supplied from the inlet of the cooling device 1000 to the nozzle unit 1300 .
- the valve may be positioned between the inlet of the cooling device 1000 and the nozzle unit 1300 to control the amount of coolant supplied from the inlet of the cooling device 1000 to the nozzle unit 1300 .
- the coolant in the open state of the valve, the coolant is movable from the inlet of the cooling device 1000 to the nozzle unit 1300 , and in the closed state of the valve, the coolant moves from the inlet of the cooling device 1000 to the nozzle unit 1300 . may be in a state where movement is restricted.
- the amount of the coolant that can move from the inlet of the cooling device 1000 to the nozzle unit 1300 may be adjusted by adjusting the opening time or the opening period of the valve.
- the valve is located between the inlet of the cooling device 1000 located at the connection part 1800 of the cooling device 1000 and the coolant temperature control unit 1200 , and the coolant temperature at the inlet of the cooling device 1000 .
- the amount of coolant supplied to the control unit 1200 may be adjusted. Specifically, in the open state of the valve, the coolant is movable from the inlet of the cooling device 1000 to the coolant temperature control unit 1200 , and in the closed state of the valve, the coolant controls the coolant temperature at the inlet of the cooling device 1000 . It may be in a state in which movement to the unit 1200 is restricted.
- the amount of the coolant that can move from the inlet of the cooling device 1000 to the coolant temperature controller 1200 may be adjusted by adjusting the opening time or the opening period of the valve.
- the coolant flow control unit 1000 may be positioned between the coolant temperature control unit 1200 and the nozzle unit 1300 in the cooling device 1000 .
- the coolant flow control unit 1100 may control the amount of coolant supplied from the coolant temperature control unit 1200 to the nozzle unit 1300 .
- the valve may be positioned between the coolant temperature control unit 1200 and the nozzle unit 1300 to control the amount of coolant supplied from the coolant temperature control unit 1200 to the nozzle unit 1300 .
- the coolant in the open state of the valve, the coolant is movable from the coolant temperature controller 1200 to the nozzle unit 1300, and in the closed state of the valve, the coolant flows from the coolant temperature controller 1200 to the nozzle unit 1300.
- the amount of the coolant that can move from the coolant temperature controller 1200 to the nozzle part 1300 can be adjusted by adjusting the opening time or opening period of the valve. In other words, by adjusting the opening time of the coolant temperature controller 1200, the amount of coolant supplied to the nozzle part 1300 can be adjusted, and the amount of coolant that is ultimately sprayed can be adjusted to control the temperature of the skin surface.
- the coolant flow control unit 1100 may be implemented as a solenoid valve, and the solenoid valve is electrically connected to the control module 1700 and the input module 1500 , and as a user operates the input module 1500 , The generated signal is input to the control module 1700 , and the control module 1700 controls the solenoid valve to be opened based on the signal to control the inflow or outflow of the coolant.
- the coolant flow control unit 1100 may be implemented as a solenoid valve, and in this case, the solenoid valve is a pulse width modulation (PWM) method according to the electrical signal of the control module 1700 of the valve.
- PWM pulse width modulation
- An operation of controlling the inflow or outflow of the coolant may be performed by adjusting the opening period.
- the solenoid valve may automatically open a plurality of opening/closing operations according to a protocol set in advance from the control module 1700 to open the valve only for a certain portion of the treatment time.
- the valve opening cycle may be a regular cycle or an irregular cycle.
- the cooling device 1000 may include a coolant temperature controller 1200 .
- the coolant temperature controller 1200 may perform a function of adjusting the physical state of the coolant.
- the coolant temperature controller 1200 may perform a function of adjusting the physical state of the coolant in the cooling device 1000 . That is, the coolant temperature control unit 1200 may perform a function of adjusting the physical state of the coolant moving in the cooling device 1000 .
- the coolant temperature control unit 1200 may adjust the temperature of the coolant.
- the coolant temperature control unit 1200 may heat the coolant.
- the coolant temperature control unit 1200 may cool the coolant.
- the coolant temperature control unit 1200 may maintain the temperature of the coolant by heating and/or cooling according to the state of the coolant.
- the coolant temperature control unit 1200 may be disposed between the coolant flow control unit 1100 and the nozzle unit 1300 .
- the coolant temperature control unit 1200 may be disposed between the coolant flow control unit 1100 and the connection unit 1800 .
- the coolant temperature control unit 1200 is disposed between the coolant flow control unit 1100 and the nozzle unit 1300 . .
- the coolant temperature control unit 1200 may include a temperature control member capable of generating thermal energy.
- the temperature control member may be implemented in various forms.
- the temperature control member may include a thermoelectric element using a Peltier effect that receives a current and absorbs heat on one surface and heats the other surface according to the direction of the applied current.
- the coolant temperature control unit 1200 includes a thermoelectric element, when a current is applied to the thermoelectric element, the first surface of the thermoelectric element generates thermal energy due to the Peltier effect, and the second surface of the thermoelectric element generates cooling energy can do.
- thermoelectric element is the coolant It may function as the temperature control unit 1200 .
- the coolant temperature control unit 1200 may generate thermal energy using chemical energy or may generate thermal energy using electrical energy. Also, the coolant temperature controller 1200 may generate thermal energy using a Joule-Thomson method using condensed gas.
- the temperature control member may use a thermodynamic cycle such as a stirling cooler or a vapor compression refrigeration cycle, or a device using a Houle-Thomson method using an expansion gas, or It may include elements.
- a thermodynamic cycle such as a stirling cooler or a vapor compression refrigeration cycle
- a device using a Houle-Thomson method using an expansion gas or It may include elements.
- the temperature control member may generate or provide cooling energy using a coolant such as carbon dioxide or liquid nitrogen.
- the temperature control member may be thermally coupled to a flow path through which the coolant in the cooling device 1000 flows.
- the temperature control member may be in surface contact with at least a portion of a flow path through which the coolant flows to provide cooling energy or thermal energy.
- thermoelectric element using the Peltier effect
- the cooling apparatus 1000 may include a nozzle unit 1300 .
- the nozzle unit 1300 may perform a function of spraying the coolant flowing inside the cooling device 1000 to the outside.
- the nozzle unit 1300 may perform a function of discharging the coolant that has passed through the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 to the outside.
- the nozzle unit 1300 may be implemented as a nozzle of any suitable shape.
- the nozzle may perform a function of spraying the coolant so that the coolant flowing in at least one area in the cooling device 1000 is ejected into the free space to reach the target area of the skin surface.
- the nozzle unit 1300 may be implemented to include a nozzle structure capable of optimizing the Joule-Thomson effect.
- the nozzle has a nozzle that is narrower than the flow path through which the high-pressure coolant flows therein. As the flow path is opened, the high-pressure coolant is guided to the nozzle along the flow path, and the coolant flowing out through the nozzle is reduced.
- It can be implemented to be sprayed in a cooled state through the nozzle due to the Thompson effect.
- the coolant sprayed through the nozzle unit 1300 may be sprayed in a cooled state due to a Joule-Thomson effect.
- the Joule-Thomson effect is a phenomenon in which the temperature decreases when the compressed gas expands. The temperature changes in relation to the thermodynamic phase consisting of pressure and temperature, and it is a phenomenon that is applied when liquefying air or cooling through a refrigerant.
- an diaphragm such as an orifice is inserted into the fluid flow path, the temperature of the fluid decreases behind the diaphragm.
- gas is free-expanded, that is, when it expands adiabatically without exchanging work with the outside, the internal energy hardly changes.
- the coolant sprayed through the nozzle unit 1300 is cooled due to a sudden pressure drop, and when the coolant is sprayed on the treatment site, the coolant comes into contact with the treatment site and heats the treated area.
- the cooling of the treated area can proceed by taking away the
- the nozzle may have abrasion resistance properties.
- the nozzle may be formed of a material that is less damaged by friction.
- the nozzle may be formed of an aluminum alloy, a steel alloy, stainless steel, or a copper alloy, but is not limited thereto.
- the nozzle unit 1300 may further include a guide unit 1310 for limiting the reaching area present on the skin surface of the coolant discharged from the nozzle unit 1300 .
- the guide part 1310 may have a shape capable of confining the coolant flowing sideways in a predetermined area after being discharged from the nozzle part 1300 and reaching the target area in the form of an impinged jet.
- the surface of the guide unit 1310 in contact with the target area may be circular or polygonal, or may be circular or polygonal having discontinuous points.
- the guide unit 1310 can control the temperature of the target area evenly by confining the coolant in a predetermined area, and after cooling the target area, the coolant can go out through a hole provided at the rear.
- the cooling apparatus 1000 may include a sensor module 1400 .
- the sensor module 1400 may detect the temperature of the target region of the skin surface and/or the physical characteristics of the cooling device 1000 .
- the sensor module 1400 may detect the temperature of the target area.
- the sensor module 1400 may include at least one temperature sensor 1410 or 1420 , and the at least one temperature sensor 1410 or 1420 may measure the temperature of a target region of the skin surface.
- At least one temperature sensor 1410 or 1420 of the sensor module 1400 is a non-contact temperature sensor using infrared or the like, thermocouples, resistance temperature detector (RTD), thermistor, IC temperature sensor, ultrasonic wave. It may be configured as a contact-type temperature sensor such as a temperature sensor.
- the sensor module 1400 may detect physical characteristics of components included in the cooling device 1000 .
- the sensor module 1400 may measure electrical characteristics such as current or voltage applied to the coolant temperature controller 1200 .
- the sensor module 1400 may include an analog or electronic circuit for measuring electrical characteristics such as current or voltage.
- the sensor module 1400 may provide the detected temperature of the target area and/or physical characteristics of the cooling device 1000 to the control module 1700 .
- the sensor module 1400 may provide the control module 1700 with a signal indicating a real-time temperature value of the target area, a current or voltage value applied to the coolant temperature controller 1200 , and the like.
- the input module 1500 may receive a user input from a user.
- the user input may be made in various forms including a button input, a key input, a touch input, a rotation input, or a voice input.
- the input module 1500 includes a button that a user can press, a wheel switch that a user can rotate, a touch sensor that detects a user's touch, a microphone that receives a user's voice input, and other various types of user input. It is a comprehensive concept that includes all types of input means that detect or receive input.
- the output module 1600 may output various information and provide it to the user.
- the output module 1600 includes a display for outputting information related to the cooling state of the cooling device, real-time temperature of the target area, a speaker for outputting sound, a haptic device for generating vibration, and other various types of output means. It is a comprehensive concept that includes
- the control module 1700 may control the overall operation of the cooling device 1000 .
- the control module 1700 may load and execute a program for the operation of the coolant flow control unit 1100 .
- the control module 1700 controls the amount of current (or voltage) applied to the coolant temperature controller 1200 to adjust the thermal energy transferred to the coolant, or the input module 1500 and the output module 1600 . ) to generate and transmit a control signal according to a user input or provide specific information to a user.
- control module 1700 is a central processing unit (CPU), a microprocessor, a processor core, a multiprocessor, an ASIC (application) according to hardware, software, or a combination thereof.
- -specific integrated circuit) or FPGA (field programmable gate array) may be implemented as a device.
- the control module 1700 may be provided in the form of an electronic circuit that performs a control function by processing electrical signals in hardware, and may be provided in the form of a program or code that drives the hardware circuit in software.
- the cooling device 1000 further includes a memory in which a control program loaded or executed by the control module 1700 is stored, and a power supply for supplying power required for the operation of the cooling device 1000 . can do.
- connection unit 1800 may be provided to connect the coolant supply unit 4000 and the cooling device 1000 .
- connection unit 1800 may include a housing 1820 for accommodating at least a portion of the coolant supply unit 4000 and/or the filter fixing module 2000 .
- connection unit 1800 may include a coupling member 1840 for mounting the coolant supply unit 4000 and/or the filter fixing module 2000 .
- the coupling member 1840 may be provided in a structure including a screw thread.
- the coupling member 1840 may be a member including a screw thread composed of a screw thread and a screw bone.
- the screw thread of the coupling member 1840 is screwed with the screw thread of the coolant supply unit 4000 , the coolant supply unit 4000 and the cooling device 1000 may be connected.
- the coupling member 1840 may include a threaded structure including at least one groove.
- a filter fixing module 2000 to be described later may be disposed between the connection unit 1800 of the cooling device 1000 and the coolant supply unit 4000 .
- the filter fixing module 2000 may include a grip part 2300
- the thread of the coupling member 1840 may include a groove formed in a shape corresponding to the shape of the grip part.
- the coolant supply unit 4000 is perforated by the perforation member 2200 of the filter fixing module 2000 , and the grip portion 2300 of the filter fixing module 2000 may be fitted into the groove of the coupling member 1840 .
- the coolant discharged from the coolant supply unit 4000 may be introduced into the cooling device 1000 through the connection unit 1800 .
- the filter fixing module 2000 may be accommodated in the coupling member 1840 of the connection unit 1800 , and the coolant supply unit 4000 is the connection unit It may be perforated by the filter fixing module 2000 while screwing with the coupling member 1840 of 1800 . Therefore, according to an embodiment of the present specification, the filter fixing module 2000 may perform a function of puncturing the coolant supply unit 4000 as well as a function of accommodating the filter on a path through which the coolant flows. .
- the filter fixing module 2000 may include a grip part 2300 protruding to the outside of the connection part 1800 for ease of use, through which the user attaches the filter fixing module 2000 to the cooling device 1000 . It can be easily mounted or removed. In this regard, it will be described later in more detail with reference to FIGS. 9 to 18 .
- the filter fixing module 2000 may include a body 2100 , a perforation member 2200 , a grip part 2300 , and a sealing member 2400 .
- the body 2100 may have a support surface for supporting the filter.
- the body 2100 accommodates at least a portion of the filter and the sealing member and may have a receiving surface connected to the support surface.
- the body 2100 may be formed in various structures capable of positioning the filter in the filter fixing module 2000 .
- the filter fixing module 2000 may be positioned between the coolant supply unit 4000 and the cooling device 1000 , and on a path through which the coolant discharged from the coolant supply unit 4000 flows into the inlet of the cooling device 1000 .
- a filter may be placed on the Accordingly, the coolant may be introduced into the cooling device 1000 after impurities included in the coolant are removed through the filter fixing module 2000 .
- the cooling system 10 according to the exemplary embodiment of the present application may be provided to minimize the possibility that the target area is contaminated by impurities included in the coolant.
- the perforation member 2200 may have a body in which a hollow hole is formed to function as a flow path for the coolant discharged from the coolant supply unit 4000 .
- the drilling member 2200 may have a first end adjacent to the support surface of the body 2100, a second end for drilling a coolant outlet of the coolant supply unit 4000, and a body extending from the first end to the second end. .
- the drilling member 2200 may receive the coolant from the coolant supply unit 4000 through the second end and output the coolant toward the cooling device 1000 through the first end.
- the grip unit 2300 may include at least one grip member 2310 or 2320 . At least one grip member 2310 or 2320 may be fitted into at least one groove included in the screw thread of the coupling member 1840 .
- the grip unit 2300 may include two grip members 2310 and 2320 .
- the thread of the coupling member 1840 may include two groove members, and the two grip members 2310 and 2320 may be accommodated in each of the two groove members included in the thread.
- the grip unit 2300 may include four grip members.
- the thread of the coupling member 1840 may include four groove members, and the four grip members may be accommodated in each of the four groove members included in the thread.
- the aforementioned grip member and the screw thread groove member of the coupling member 1840 may be formed in a symmetrical structure with respect to the central axis.
- the aforementioned grip member and the screw thread groove member of the coupling member 1840 may be formed in an asymmetrical structure with respect to the central axis.
- the filter fixing module 2000 may be mounted on the connection unit 1800 of the cooling device 1000 .
- the above-described structure is merely an example, and various structures in which the grip part 2300 can be connected to the coupling member 1840 may be provided.
- At least one grip member 2310 or 2320 may be provided to protrude to the outside of the cooling device 1000 have. Accordingly, the user can easily apply a force to the at least one grip member 2310 or 2320 protruding to the outside of the cooling device 1000, and connect the at least one grip member 2310 or 2320 to the coupling member 1840. It can be easily separated from the groove member formed in the thread of the For example, when the user applies a force in a direction in which the at least one or more grip members 2310 or 2320 approach each other, the at least one grip member 2310 or 2320 is separated from the groove member formed in the thread of the coupling member 1840 . can be
- the user cools the filter fixing module 2000 by applying a force to at least one grip member 2310 or 2320 when the use of the coolant supply unit 4000 (eg, cartridge or coolant tank) is completed. It can be easily detached from the device 1000 .
- the coolant supply unit 4000 eg, cartridge or coolant tank
- the coolant supply unit 4000 eg, a cartridge or a coolant tank
- at least a gaseous coolant may remain in the coolant supply unit.
- the gaseous coolant is exposed to atmospheric pressure, it instantaneously expands, thereby causing noise and inconvenience to the user.
- the user when the use of the coolant supply unit 4000 is completed, the user can separate the coolant supply unit 4000 from the coupling member 1840 . .
- the user may rotate the cartridge-shaped coolant supply unit 4000 in one direction so that the screw thread of the cartridge and the screw thread of the coupling member 1840 are separated.
- a fluid passage may be formed inside the coupling member 1840 .
- the gaseous coolant remaining in the coolant supply unit 4000 eg, cartridge or coolant tank
- the user may apply a force to the at least one grip member 2310 or 2320 to separate the at least one grip member 2310 or 2320 from the groove formed in the screw thread of the coupling member 1840 .
- the filter fixing module 2000 may include a sealing member 2400 that prevents leakage of coolant flowing into the filter fixing module 2000 through the perforation member 2200 .
- the filter fixing module 2000 is the first sealing member 2410 accommodated in the receiving surface extending in the first direction with respect to the body 2100 and the second direction opposite to the first direction with respect to the body.
- a second sealing member 2420 through which the extended perforation member 2200 passes may be included.
- the first sealing member 2410 may perform a function of reducing leakage of a coolant flowing from the filter fixing module 2000 to the cooling device 1000 .
- the second sealing member 2420 has a function of reducing leakage of the coolant to be provided from the coolant supply unit 4000 to the hollow hole of the perforation member 2200 of the filter fixing module 2000 to the outer surface of the perforation member 2200 . can be performed.
- the first sealing member 2410 may include a hollow hole through which the coolant may flow.
- a hollow hole forming a passage through which the coolant may flow may be formed in the center of the first sealing member 2410 .
- the second sealing member 2420 may include a through hole through which the perforation member 2200 may pass.
- a through hole through which the body of the perforating member 2000 can pass may be formed in the center of the second sealing member 2410, and the shape and size of the through hole may correspond to the shape and size of the body of the perforating member. have.
- the inner diameter of the second sealing member 2420 defined by the through hole may be larger than the outer diameter of the perforation member 2200 .
- the filter fixing module 2000 may be compatible with both the cartridge type coolant supply unit 4000 and the coolant tank type coolant supply unit 4000 .
- the perforation member 2200 of the filter fixing module 2000 may be provided to perforate a hose connected to the cartridge or the coolant tank.
- the structure and shape of the filter fixing module 2000 will be described later in detail with reference to FIGS. 9 to 18 .
- FIG 5 is a view showing a process of cooling the target through the cooling system 10 according to an embodiment of the present specification.
- the control module 1700 may control whether the coolant introduced into the cooling device 1000 is sprayed and/or the amount of coolant injected through the coolant moving hole formed inside the connection part 1800 .
- control module 1800 may control the coolant flow adjusting unit 1100 to adjust whether or not the coolant is sprayed and/or the amount of coolant sprayed.
- control module 1700 may control the coolant temperature controller 1200 to control the temperature of the coolant flowing inside the cooling device 1000 .
- the cooling apparatus 1000 may cool the target by spraying a coolant having a controlled temperature characteristic to the target on the skin surface through the nozzle unit 1300 to provide cooling energy to the target.
- the control module 1700 controls the temperature control member of the coolant temperature controller 1200 to provide thermal energy to the coolant flowing through the tube of the coolant temperature controller 1200 to adjust the coolant temperature to a preset temperature.
- the control module 1700 controls the temperature of the coolant by controlling the current (or voltage) value applied to the temperature control member of the coolant temperature controller 1200 to increase or decrease or maintain the thermal energy applied to the coolant. can do.
- the cooling system 10 may control the temperature of the target to be a preset temperature by controlling the temperature of the injected coolant.
- the sensor module 1400 may obtain temperature information by measuring the temperature of the target that changes as cooling energy by the coolant is transferred to the target, and may transmit the obtained temperature information to the control module 1700 .
- the temperature information acquired by the sensor module 1400 is information about the temperature of a component in the cooling device 1000 (eg, the temperature of the temperature control member of the coolant temperature control unit 1200 ) or the cooling device 1000 . It may further include information about the ambient temperature of the.
- the sensor module 1400 may include a plurality of sensors for acquiring various temperature information.
- the control module 1700 may generate a control signal for controlling the current applied to the temperature control member of the coolant temperature control unit 1200 based on the temperature information obtained from the sensor module 1400 .
- control module 1700 may use feedback control for controlling the power applied to the temperature control member of the coolant temperature control unit 1200 using the target temperature information obtained from the sensor module 1400 .
- control module 1700 may control the temperature of the target using the following proportional integral differential (PID) control equation.
- PID proportional integral differential
- P(t) is an output value or a control value of a signal that the control module 1700 controls the temperature control member
- error(t) is the target temperature and the sensor module to be controlled by the control module 1700 It means a difference value of the temperature of the target measured in step 1400
- Cp, Ci, and Cd may mean a gain value or a gain selected in a tuning process.
- P, PI, and PD control can be used because each term is omitted from the above control equation.
- control module 1700 provides power corresponding to a specific temperature (or coolant temperature) of the target to be controlled in consideration of the type of coolant, the contact area between the temperature control member of the coolant temperature controller 1200 and the coolant flow path, etc. may be provided to the temperature control member.
- the input module 1500 may obtain a user input for setting a cooling time, a control temperature of a target (or a control temperature of a coolant), and the like.
- the user may preset the time for which the coolant is sprayed to the target by setting the spraying time of the coolant through the input module 1500 .
- the user may preset the temperature of the target to be controlled through the input module 1500 .
- the input module 1500 that has obtained the user's input may transmit input information related to the user's cooling time and/or the control temperature of the target to the control module 1700 , and the control module 1700 may transmit the coolant material based on the input information.
- the current (or voltage) value applied to the temperature control member of the temperature control unit 1200 or the opening/closing time of the valve of the coolant flow control unit 1100 may be controlled.
- the input module 1500 may obtain an input instructing the start of cooling in addition to input information related to a cooling condition including a cooling time and a control temperature of a target. For example, when input of input information related to the above-described cooling condition is completed, the user may input an input instructing the start of cooling through the input module 1500 .
- the input module 1500 may be implemented to transmit an input signal instructing the start of cooling to the control module 1700 , and the control module 1700 may be configured to flow coolant in response to a user input instructing the start of cooling. It may be implemented to control opening and closing of a valve of the control unit 1100 or to adjust a current (or voltage) value applied to the temperature control member of the coolant temperature control unit 1200 .
- the input information related to the cooling condition and the input information instructing the start of cooling may be configured to be obtained through different input modules 1500 .
- input information related to the cooling condition is obtained through the first input module 1510
- input information related to the cooling condition is obtained from a second input module 1520 separate from the first input module 1510 .
- the input module may be provided to obtain input information related to a cooling condition and input information instructing the start of cooling through a single input module, without being limited thereto.
- the output module 1600 may output various information related to the cooling device 1000 and provide it to the user.
- the output module 1600 may output real-time temperature information of the target area through the display.
- the sensor module 1400 may measure the temperature information of the target and may transmit the measured temperature information of the target to the control module 1700 .
- the control module 1700 may transmit the target temperature information to the output module 1600
- the output module 1600 may be configured to output the temperature information of the target area based on the obtained target temperature information.
- the output module 1600 may output information related to the state of the cooling device 1000 and provide it to the user.
- the control module 1700 determines whether the first temperature sensor 1410 and the second temperature sensor 1420 are normal based on the temperature information obtained from the first temperature sensor 1410 and the second temperature sensor 1420 . can judge In this case, the control module 1700 may provide a result of determining whether the first temperature sensor 1410 and the second temperature sensor 1420 are normal to the user through the output module 1600 . For example, when it is determined that the first temperature sensor 1410 and the second temperature sensor 1420 operate normally, a first alarm is output through the output module 1600 in the form of a speaker, and the first temperature sensor 1410 ) and the second temperature sensor 1420 may be implemented to output a second alarm through the output module 1600 in the form of a speaker when it is not determined that at least one operates normally.
- the cooling device 1000 may include a body including a body part and a gripping part, and the above-described components of the cooling device 1000 may be disposed in the body part or the gripping part.
- the main body of the cooling device 1000 may be divided into a body part and a grip part.
- the main body of the cooling device 1000 may include a body portion on which the filter fixing module 2000 and the coolant supply unit 4000 are mounted, and a gripping portion that can be gripped by the user.
- the body part and the grip part may be implemented as an integral body, or may be physically separated and combined through assembly to configure the cooling device 1000 .
- a coolant flow control unit 1100 , a coolant temperature control unit 1200 , a nozzle unit 1300 , a sensor module 1400 , and a connection unit 1800 may be disposed inside the body part.
- the coolant flow control unit 1100, the coolant temperature control unit 1200, the nozzle unit 1300, the sensor module 1400 and the connection unit 1800 are inside the body part with the central axis CA of the body part as the center. can be placed.
- the coolant temperature control unit 1200 , the nozzle unit 1300 , and the sensor module 1400 are disposed close to the front end F of the body portion, and the coolant flow control unit 1100 and the connection unit 1800 are connected to the body portion. It may be disposed close to the rear end (R).
- an input module 1500 and an output module 1600 may be additionally disposed in the body portion.
- the input module 1500 includes a plurality of input devices and may be disposed close to the front end F or the rear end R of the body, respectively.
- the output module 1600 includes a plurality of output devices and may be disposed close to the front end F or the rear end R of the body, respectively.
- the central axis CA may refer to an axis formed in the longitudinal direction passing through the center of the body portion or an axis parallel thereto.
- connection part 1800 may constitute at least a part of the main body.
- the connection part 1800 may be formed at the rear end R of the body part of the cooling device 1000 .
- the connection part 1800 may be implemented in a form coupled to the body part.
- the filter fixing module 2000 may be mounted on the main body.
- the grip members 2310 and 2320 of the filter fixing module 2000 may be mounted or detached from the cooling device 1000 at the rear end R of the body portion.
- the grip members 2310 and 2320 may be mounted on the cooling device 1000 or separated from the cooling device 1000 through the connection portion 1800 formed at the rear end R of the body portion.
- the grip members 2310 and 2320 may be mounted on the cooling device 1000 or separated from the cooling device 1000 through at least one groove formed in the screw thread of the connection part 1800 formed at the rear end of the body part.
- a control module 1700 may be disposed inside the gripper.
- the control module 1700 may be disposed in the grip part along the length direction of the grip part.
- the input module 1500 may be disposed inside or outside the grip part.
- the input module 1500 such as a button for instructing the start of cooling
- the input module 1500 may be disposed at a portion where the user's finger is positioned according to the user's grip in the grip unit. Accordingly, the user can easily control the operation of the cooling device 1000 , such as instructing the start of cooling by pressing a button while holding the cooling device 1000 .
- an input module 1500 such as a wheel switch or button for setting cooling conditions such as a cooling time and a control temperature of a target may be disposed outside the gripping part (eg, outside the distal end of the gripping part). Accordingly, the user can easily set the cooling conditions and the like before starting the cooling.
- the output module 1600 may be disposed inside or outside the gripper.
- the state of the cooling operation eg, temperature information of the target and the remaining time of the cooling operation, etc.
- an output module 1600 such as a display may be disposed. Accordingly, the user can easily obtain information on the cooling state (eg, real-time target temperature, remaining cooling time, etc.) while performing a cooling operation using the cooling device 1000 .
- the gripper includes a switch for controlling whether or not the cooling device operates, a power supply for supplying power to the cooling device 1000, and a blower for dissipating heat generated from the power supply.
- a port and the like may be disposed.
- the arrangement of the components of the cooling device 1000 in the body portion and the grip portion of the cooling device 1000 is not limited to the above description.
- FIG. 7 is a diagram illustrating a coolant temperature controller 1200 according to an embodiment of the present specification.
- the coolant temperature control unit 1200 may include a temperature control member 1220 , a porous member 1240 , a heat insulating member 1260 , and a tube.
- the tube may be thermally coupled to the temperature control member 1220 .
- the tube may include a first surface in contact with one surface of the first temperature control member 1221 and a second surface in contact with one surface of the second temperature control member 1222 .
- the tube may receive thermal energy from the first and second temperature control members 1221 and 1222 through the first and second surfaces.
- the pipe shown in FIG. 7 may be a single pipe with the pipe in which the inlet 1110 shown in FIG. 10 is formed.
- the pipe shown in FIG. 7 may be a pipe separate from the pipe in which the inlet 1110 shown in FIG. 10 is formed, but may be a pipe connected to each other.
- the tube and the temperature control member 1220 may be configured in a shape for efficiently transferring thermal energy or cooling energy.
- at least a portion of the tube and the temperature control member 1220 may be implemented in a rectangular parallelepiped shape in order to be in surface contact.
- the shape of the tube and the temperature control member 12200 is not limited to the aforementioned rectangular parallelepiped, and may be implemented in various shapes for making surface contact.
- first temperature control member 1221 and the second temperature control member 1222 may be fixed in a state in surface contact with the tube.
- the temperature control member 1220 may include one surface and the other surface that absorb or generate heat according to the direction of the applied current.
- one surface of the temperature control member 1220 in surface contact with the tube may be configured as a surface that generates heat according to the direction of an applied current, and the other surface of the temperature control member 1220 is a surface that absorbs heat. It may be implemented to be fixedly coupled to In this case, the temperature control member 1220 may transmit thermal energy to the coolant flowing through the inside of the tube through one surface.
- a porous member 1240 may be disposed inside the tube.
- the porous member 1240 disposed inside the tube may transfer thermal energy transferred from the temperature control member 1220 through the tube to the coolant.
- the porous member 1240 may have a porous structure including a plurality of pores, and since the contact area with the coolant may be increased due to the porous structure, heat energy is transferred to the coolant passing through the plurality of pores. It can perform the function of delivering more efficiently.
- the heat insulating member 1260 may be disposed around one side and the other side of the tube of the coolant temperature control unit 1200 .
- the first heat insulating member 1261 may be disposed and fixed between the nozzle unit 1300 and one side of the tube positioned on the nozzle unit 1300 side. Through this, the first heat insulating member 1261 may thermally block external components including the nozzle unit 1300 from the coolant temperature control unit 1200 .
- the second heat insulating member 1262 may be disposed and fixed between the coolant flow control unit 1100 and the other side of a tube positioned on the coolant flow control unit 1100 side. Through this, the second heat insulating member 1262 may thermally block external components including the coolant flow control unit 1100 from the coolant temperature control unit 1200 .
- the heat insulating member 1260 may be made of a material having a thermal conductivity of 10 W/(m*K) or less.
- the heat insulating member 1260 may be made of a material of Teflon.
- the position, thermal conductivity, material, etc. of the above-described heat insulating member are only examples, and the heat insulating member for thermally blocking external components from the coolant temperature control unit 1200 is provided at any suitable position and any suitable thermal conductivity. Of course, it may be provided as a material having
- FIG. 8 is a diagram illustrating a sensor module 1400 according to an embodiment of the present specification.
- the sensor module 1400 may include a first temperature sensor 1410 and a second temperature sensor 1420 .
- the sensor module 1400 may be disposed inside the body part.
- the sensor module 1400 may be disposed on the outside of the nozzle unit 1300 and fixed.
- the sensor module 1400 and the nozzle unit 1300 may be disposed inside the body so that the center of the measurement area of the sensor module 1400 and the center of the coolant injection area of the nozzle unit 1300 coincide.
- the nozzle unit 1300 may include a guide unit 1310
- the guide unit 1310 may include a target limiting member 1312 in contact with the skin and defining a target area.
- the sensor module 1400 has the central axis CA of the body portion such that the center C1 of the measurement area of the sensor module 1400 and the center C2 of the target area defined by the target limiting member 1312 are substantially the same. ) with a predetermined angle and may be fixed to the outer periphery of the nozzle unit 1300 .
- the sensor module 1400 may include at least one temperature sensor.
- the sensor module 1400 may include a first temperature sensor 1410 and a second temperature sensor 1420 .
- the first temperature sensor 1410 and the second temperature sensor 1420 may be disposed inside the body part positioned in the same direction with respect to the nozzle part 1300 .
- the first temperature sensor 1410 and the second temperature sensor 1420 may be disposed in the lower region of the inner surface of the body part with respect to the nozzle part 1300 .
- the front end of the first temperature sensor 1410 may be disposed relatively closer to the front end F of the body portion than the front end of the second temperature sensor 1420 . That is, the first temperature sensor 1410 may be disposed closer to the front end of the body portion than the second temperature sensor 1420 .
- At least one of the first temperature sensor 1410 and the second temperature sensor 1420 may measure temperature information of the target.
- the target temperature information may be obtained based on the target temperature measured by the first temperature sensor 1410 and the second temperature sensor 1420 .
- the temperature information of the target may be obtained by giving weight to the temperature information of the target measured by the first and second temperature sensors, or by selecting one of the temperature information of the target measured by the first and second temperature sensors.
- target temperature information may be acquired using one of the first temperature sensor 1410 and the second temperature sensor 1420 .
- first temperature sensor 1410 and the second temperature sensor 1420 operate normally, any one of the first temperature sensor 1410 and the second temperature sensor 1420 Only one temperature sensor is activated to obtain temperature information of the target.
- a lens may be additionally provided at the front end of the second temperature sensor 1420 .
- the first and second temperature sensors 1410 and 1420 By using at least one of the first and second temperature sensors 1410 and 1420 , power required to operate the temperature sensor can be saved, and the lifespan of the sensor module 1400 can be increased.
- the first temperature sensor 1410 and the second temperature sensor 1420 may be symmetrically disposed inside the body part with respect to the central axis CA of the body part as shown in FIG. 8(b) .
- the first temperature sensor 1410 and the second temperature sensor 1420 are the center (
- the sensor module 1400 has a predetermined angle with respect to the central axis CA of the body portion so that C1) and the central portion C2 of the target area defined by the target limiting member 1312 are substantially the same, and the nozzle portion 1300. Of course, it can be fixed around the outer periphery of the.
- the above-described arrangement of the sensor module 1400 is merely an example, and the technical spirit of the present specification is not limited thereto, and any suitable method capable of reducing the size of the cooling device 1000 while accurately measuring the temperature of the target area structure can be implemented.
- the cooling apparatus 1000 may further include a cryogen pressure keeper for maintaining the pressure of the coolant at a preset pressure.
- the coolant pressure maintaining unit may be provided in the cooling device 1000 .
- the coolant pressure maintaining unit may be located in a gripping portion that can be gripped by a user.
- the coolant pressure maintaining unit may be located in the body portion.
- the coolant pressure maintaining unit maintains the coolant in a high pressure state, thereby preventing pressure loss of the coolant and spraying the coolant at a fast response speed.
- the coolant pressure maintaining unit may cool the coolant.
- the coolant pressure maintaining unit may cool the coolant using a Peltier element.
- the coolant pressure maintaining unit cools the coolant before it flows into the coolant temperature control unit 1200 , so that the coolant flowing into the coolant temperature control unit 1200 is maintained at a high pressure.
- the coolant pressure maintaining unit may be provided to further include a heat dissipation unit for dissipating heat generated from the Peltier element.
- the coolant pressure maintaining unit may be applied to the cooling device 1000 using the coolant supply unit 4000 in the form of a cartridge shown in FIG. 2 .
- the coolant pressure maintaining unit may be more advantageously applied to the cooling device 1000 using the coolant supply unit 4000 in the form of a coolant tank shown in FIG. 3 .
- the filter fixing module 2000 disclosed herein may be provided in a structure capable of accommodating the filter therein while puncturing the coolant supply unit 4000 .
- the cooling device 1000 disclosed herein is a coupling member ( 1840) may be included.
- the filter fixing module 2000 may be formed in a structure in which a coolant supply unit 4000 screwed to a thread formed on the coupling member 1840 is perforated.
- the filter fixing module 2000 may be formed in a structure capable of accommodating the filter inside the filter fixing module 2000 .
- the coolant discharged from the coolant supply unit 4000 is cooled through the filter while the coolant supply unit 4000 is coupled to the cooling device 1000 . It may be provided in a structure for accommodating the filter so as to be introduced into the device 1000 .
- connection part 1800 of the cooling device 1000 may be provided in a structure having a screw thread to be screwed with the coolant supply part 4000 .
- the coupling member 1840 of the connection unit 1800 which will be described later, may include a screw thread structure, and thus may be provided to be screwed with the screw thread of the coolant supply unit 4000 .
- FIG. 9 is a view showing an internal structure of the cooling device 1000 to which the filter fixing module 2000 is mounted according to an embodiment of the present specification.
- the filter fixing module 2000 may be mounted on the connection unit 1800 of the cooling device 1000 , thereby supplying coolant to the inlet 1110 of the coolant flow control unit 1100 .
- the filter fixing module 2000 may be mounted on the inner surface of the coupling member 1840 screwed to the screw thread of the inner surface of the housing 1820 of the connection unit 1800 .
- the front end FE of the coupling member 1840 may be connected to one end of the inlet 1110 of the coolant flow control unit 1100.
- the tip of the coupling member 1840 (FE) and the inlet 1110 of the coolant flow control unit 1100 may be connected.
- the filter fixing module 2000 may be provided in a structure that provides a flow path of the coolant connected to the front end FE of the coupling member 1840 . Accordingly, coolant may be introduced from the filter fixing module 2000 to the inlet 1110 of the coolant flow control unit 1100 .
- FIG. 10 is an exploded view of the cooling device 1000 on which the filter fixing module 2000 is mounted according to an embodiment of the present specification.
- a screw line 1120 may be formed on the outside of the inlet 1110 of the coolant flow control unit 1100 .
- connection part 1800 may be provided in a structure including a base 1841 , a first screw thread structure 1842 , and a second screw thread structure 1844 .
- first screw thread structure 1842 may be provided as a structure including at least one or more grooves 1846 .
- the first screw thread structure 1842 and/or at least one groove 1846 may have a structure capable of receiving or coupling the filter fixing module 2000 .
- the grip portion 2300 of the filter fixing module 2000 is accommodated in at least one or more grooves 1846 formed in the first screw thread structure 1842, so that the filter fixing module 2000 is detachably attached to the coupling member 1840. can be mounted This will be described later in detail with reference to FIGS. 12 to 18 .
- the second thread structure 1844 may be formed outside the first thread structure 1842 .
- the second screw thread structure 1844 may be formed on the outer surface of the coupling member 1840 on which the first screw thread structure 1844 is formed.
- the second screw thread structure 1844 may be provided to be screwed with the housing 1820 of the connection part 1800 .
- a screw line 1822 having a screw thread and a screw trough corresponding to the second screw line structure 1844 may be formed on the inner surface of the housing 1820 .
- the second screw structure 1844 and the screw line 1822 on the inner surface of the housing 1820 are screwed together, so that the coupling member 1840 and the housing 1820 may be coupled.
- the housing 1820 may be screwed to surround the outside of the coupling member 1840, and through this structure, the components of the cooling device 1000 (eg, the coupling member 1840, the coolant flow control unit ( By providing the inlet 1110 of 1100) or the filter fixing module 2000 to be surrounded by the housing 1820, it can be protected from an external impact or the like.
- the housing 1820 may be provided to have a structure coupled to a coupling member formed outside the body portion of the body of the cooling device 1000 .
- a coupling member having a structure corresponding to a coupling member formed on the outside of the body portion of the main body may be formed on the outer surface of the housing 1820 , and the coupling member of the housing 1820 is formed on the outside of the body portion of the body By being fitted to the housing 1820 , it may be fixedly coupled to the body portion of the main body of the housing 1820 .
- the housing 1820 is a separate component from the body of the cooling device 1000 , and the housing 1820 is illustrated as being coupled to the body of the cooling device 1000 .
- this is only an example, and while the housing 1820 is formed in a single structure with the body of the cooling device 1000 , the screw thread is screwed to the second thread structure 1844 of the coupling member 1840 and the body.
- it may be provided to be formed on the inner surface of the.
- FIG 11 is a perspective view of a coupling member 1840 to which the filter fixing module 2000 according to an embodiment of the present specification is mounted.
- the coupling member 1840 may be provided as a structure further including a third screw structure 1848 .
- the third screw thread structure 1848 may be formed on the opposite side of the first screw thread structure 1842 with respect to the base 1841 of the coupling member 1840 .
- the third screw structure 1848 may be provided to have a screw thread and a screw trough corresponding to the screw line 1120 formed on the outside of the inlet 1110 of the coolant flow control unit 1100 described above. Accordingly, the third threaded structure 1848 and the threaded thread 1120 of the inlet 1110 may be threaded. Through this, the coupling member 1840 and the coolant flow control unit 1100 may be connected.
- the coolant movement path of the filter fixing module 2000 may be connected to one end of the inlet 1110 of the coolant flow control unit 1100 through the coolant movement hole of the coupling member 1840 , and through this, the coolant supply unit The coolant discharged from 4000 may be introduced into the inlet 1110 of the coolant flow control unit 1100 through the coolant movement hole of the filter fixing module 2000 and the coupling member 1840 .
- the above-described structure is only an example, and by using a coupling member having an appropriate shape for mounting the filter fixing module 2000 to the cooling device 1000 , the coolant is transferred from the filter fixing module 2000 to the coolant flow control unit Any suitable coupling structure may be provided to feed into the inlet 1110 of 1100 .
- FIG. 12 is a view showing an aspect in which the filter fixing module 2000 and the coupling member 1840 are coupled according to an embodiment of the present specification.
- the filter fixing module 2000 is accommodated in or coupled to the coupling member 1840 by receiving the grip members 2310 and 2320 in at least two grooves 1846 formed on the inner surface of the coupling member 1840 , respectively.
- the coolant supply unit 4000 may be screwed with the first screw structure 1842 of the coupling member 1840 in a state where the filter fixing module 2000 is accommodated in the coupling member 1840 .
- the filter fixing module 2000 may be provided to be disposed between the cooling device 1000 and the coupling member 1840 of the cooling device 1000 and the coolant supply unit 4000 screwed together.
- the filter fixing module 2000 may include a grip part 2300 .
- the grip unit 2300 may include at least two or more grip members 2310 and 2320 .
- the grip part 2300 may include a first grip member 2310 and a second grip member 2320 .
- a user can easily mount or detach the filter fixing module 2000 from the cooling device 1000 by applying a force to the first grip member 2310 and the second grip member 2320 .
- the coupling member 1840 may have a first screw thread structure 1842 including at least one groove 1846 as described above.
- the first grip member 2310 and the second grip member 2320 may be fitted into at least one groove 1846 of the first screw thread structure 1842 .
- the first and second grip members 2310 and 2320 may be provided in the shape of a curved flat plate.
- each of the partial regions of the curved flat plate shape of the first and second grip members 2310 and 2320 may be provided in a size and shape corresponding to at least one groove 1846 of the first screw thread structure 1842 .
- the first grip member 2310 is fitted into the first groove 1846a of the first screw thread structure 1842
- the second grip member 2320 is the second groove 1846b of the first screw thread structure 1842.
- the structure and coupling relationship of the filter fixing member 2000 and the coupling member 1840 shown in FIG. 12 are merely examples and are not limited thereto.
- various numbers and types of grip members may be used to detachably mount the filter fixing member 2000 to the coupling member 1840 .
- the filter fixing module 2000 may be mounted to the connection part 1800 of the cooling device 1000 by including a coupling member of any suitable type other than the grip member.
- FIG. 13 is a view illustrating an aspect in which the coolant supply unit 4000 is screwed to the coupling member 1840 and drilled by the perforation member 2200 of the filter fixing module 2000 according to an embodiment of the present specification.
- the first grip member 2310 of the filter fixing module 2000 is in the first groove 1846a of the first screw structure 1842 of the coupling member 1840 .
- the second grip member 2320 of the filter fixing module 2000 is accommodated in the second groove 1846b of the first screw thread structure 1842 of the coupling member 1840, whereby the filter fixing module 2000 is coupled. It may be mounted to the member 1840 .
- the coolant supply unit 4000 may have a structure that is perforated by the filter fixing module 2000 and can be coupled to the coupling member 1840 .
- the coolant supply unit 4000 may include a coolant outlet hole punched by the perforation member 2200 of the filter fixing module 2000 .
- the diameter of the coolant outlet may be larger than the outer diameter of the body of the perforation member 2200 .
- the body of the perforation member 2200 may perforate the coolant outlet of the coolant supply unit 4000 .
- the outer surface of the body of the perforation member 2200 may be made of a material with high rigidity (eg, steel or stainless steel).
- the coolant outlet of the coolant supply unit 4000 may be made of a material with low rigidity (eg, an aluminum alloy or a copper alloy).
- the outer surface of the body of the perforation member 2200 may have a relatively larger thickness than the coolant outlet of the coolant supply unit 4000 . Through this, the perforation member 2200 may easily punch a hole in the coolant supply unit 4000 .
- the coolant supply unit 4000 may have a structure capable of being coupled to the first screw structure 1842 of the coupling member 1840 .
- the coolant supply unit 4000 may have a screw thread structure including a screw thread and a screw trough corresponding to the first screw thread structure 1842 . Accordingly, the coolant supply unit 4000 may be fixed to the coupling member 1840 by screwing the coupling member 1840 with the first screw thread structure 1842 .
- the filter fixing module 2000 disclosed herein may be provided in a structure capable of piercing the coolant supply unit 4000 while accommodating the filter therein, the filter fixing module 2000 may include the coolant supply unit 4000 as a coupling member. may provide the advantageous advantage that the coolant discharged from the coolant supply 4000 may be configured to pass through a filter, while more easily coupled to 1840 .
- FIGS. 14 to 16 is an exploded view of the filter fixing module 2000 according to an embodiment of the present specification.
- 15 is a view showing the body 2100 and the grip portion 2300 of the filter fixing module 2000 according to an embodiment of the present specification.
- 16 is a view illustrating a relationship between the body 2100 and the first sealing member 2410 of the filter fixing module 2000 according to an embodiment of the present specification.
- the filter fixing module 2000 includes a body 2100, a perforation member 2200, grip members 2310 and 2320, and at least one sealing member 2400. can do.
- the body 2100 may be formed in a structure for accommodating at least a portion of the filter and the sealing member 2400 .
- the body 2100 accommodates at least a portion of the filter and the sealing member by surrounding the support surface 2120 for supporting the filter and the sealing member 2400 , and at least side surfaces of the filter and the sealing member 2400 . It may be provided in a structure including a receiving surface 2140 for
- the support surface 2120 may be provided to have a shape corresponding to the shape of the filter and the sealing member 2400 .
- the support surface 2120 may be provided in a circular shape.
- the receiving surface 2140 may be connected to the supporting surface 2120 of the body 2100 .
- the receiving surface 2140 may be provided to extend along the first direction from the outer edge of the support surface 2120 .
- the receiving surface 2140 may be provided to have a shape corresponding to the shapes of the filter and the sealing member accommodated in the receiving surface 2140 .
- the receiving surface 2140 may be provided to surround at least the side surfaces of the filter and the sealing member 2400, so the receiving surface 2140 is the filter and It may be provided to have a curved surface corresponding to the curved surface of the sealing member 2400 .
- the shape of the filter has a polygonal or star shape, but its vertex has a size corresponding to the receiving surface 2140, and the contact surface between the receiving surface 2140 and the sealing member 2400 is increased by increasing the amount of coolant. Sealing can be improved.
- the body 2100 may further include a hole that can function as a passage of the coolant.
- the body 2100 is located at the center of the support surface 2120 and may be provided in a structure including a connection hole connected to the second end of the perforation member 2200 .
- the connection hole of the body 2100 may receive the coolant output from the second end of the perforation member 2200 and perform a function of a coolant flow passage for outputting the coolant in the direction of the cooling device 1000 .
- the coolant output from the connection hole of the body 2100 passes through the filter accommodated by the support surface 2120 and the receiving surface 2140 of the body 2100 , and the coolant flow control unit 1100 of the cooling device 1000 . ) may be supplied to the inlet 1110 . Since the coolant from which impurities have been removed through the structure of the filter fixing module 2000 can be introduced into the cooling device 1000 and sprayed on the target, infection of the cooling device 1000 and the target due to impurities can be minimized. have.
- the perforation member 2200 may be connected to the support surface 2120 of the body 2100 , and may be provided to perform a function of perforating the coolant supply unit 4000 .
- the perforation member 2200 may include a first end adjacent to the support surface 2120 of the body 2100 , a second end receiving coolant discharged from the coolant supply unit 4000 , and a second end direction from the first end. It may be provided in a structure including an extended body.
- the perforation member 2200 may be provided to extend along a second direction opposite to the first direction in which the receiving surface 2140 extends with respect to the supporting surface 2120 of the body 2200 .
- the body of the perforation member 2200 includes a hollow hole formed therein to output the coolant discharged from the coolant supply unit 4000 to the inlet 1110 side of the coolant flow control unit 1100 through the coupling member 1840. It may be provided in a structure that
- the grip members 2310 and 2320 extend from the body 2100 and may be provided in a structure that can be mounted on the connection part 1800 .
- the grip members 2310 and 2320 may be provided to extend from the support surface 2120 toward the outside of the support surface 2120 on which the receiving surface 2140 is not formed. More specifically, the grip members 2310 and 2320 may be provided to extend along a second direction opposite to the first direction from the outside of the support surface 2120 on which the receiving surface 2140 is not formed.
- the first grip member 2310 and the second grip member 2320 may be provided in a substantially parallel flat plate shape. At this time, as described above, the first grip member 2310 and the second grip member 2320 are accommodated in at least one groove 1846 included in the thread of the coupling member 1840 of the connection part 1800, thereby cooling device. It may be provided to have a size and shape corresponding to the size and shape of at least one or more grooves 1846 to be mounted on the 1000 .
- first grip member 2310 and the second grip member 2320 may be provided in a bent flat plate shape.
- each of the first grip member 2310 and the second grip member 2320 has a predetermined angle with the first region P1 extending in the second direction and the second direction. It may be provided in a structure of a bent flat plate shape including the second region P2 extending to .
- the first grip member 2310 has a bent flat plate shape including a first area P1 extending in the second direction and a second area P2 extending in a third direction having a predetermined angle with the second direction. It can be provided in the structure of Meanwhile, the second grip member 2320 has a bent flat plate shape including a first area P1 extending in the second direction and a second area P2 extending in a fourth direction having a predetermined angle with the second direction. It can be provided in the structure of In this case, the fourth direction may be different from the third direction.
- the angle formed by the first area P1 of the first grip member 2310 and the second area P2 of the first grip member 2310 is the first area P1 of the second grip member 2320 . and the angle formed by the second region P2 of the second grip member 2320 may be substantially the same. Accordingly, the first grip member 2310 and the second grip member 2320 may be provided to have a substantially symmetrical structure with respect to the central axis.
- the first area P1 of the first grip member 2310 and the first area P1 of the second grip member 2320 may be provided in a structure that is substantially parallel and spaced apart by a first distance.
- the second area P2 of the first grip member 2310 and the second area P2 of the second grip member 2320 may be provided in a structure spaced apart by a second distance different from the first distance. .
- the second distance may be smaller than the first distance, but according to a preferred example, the first grip member 2310 and the second grip member 2320 may be provided so that the second distance is greater than the first distance.
- At least a portion of the first region P1 of the first grip member 2310 is accommodated in at least one groove 1846a included in the screw thread of the coupling member 1840 of the connection part 1800 as described above. It may be mounted on the cooling device 1000 .
- at least a portion of the second region P2 of the second grip member 2320 is accommodated in at least one groove 1846b included in the screw thread of the coupling member 1840 of the connection part 1800 as described above. It may be mounted on the cooling device 1000 .
- the first grip member 2310 and the second grip member 2320 may protrude to the outside of the cooling device 1000 .
- the filter fixing module 2000 may include at least one sealing member 2400 .
- At least one or more sealing members 2400 may function to prevent leakage of coolant and block coolant from the outside.
- the filter fixing module 2000 may include a support surface 2120 and a first sealing member 2410 accommodated in the receiving surface 2140 .
- the first sealing member 2410 is provided in the form of a flat disk, is disposed in the first direction with respect to the body 2100 , and may be accommodated in the filter fixing module 2000 by the receiving surface 2140 .
- the first sealing member 2410 may be formed of a material such as Teflon.
- the first sealing member 2410 may function to prevent the coolant output through the first end of the perforation member 2200 from leaking to the outside.
- the first sealing member 2410 may perform a function of reducing the leakage of coolant through the contact surface between the support surface 2120 and the first sealing member 2410 .
- the filter in order to increase the sealing property by increasing the contact surface between the support surface 2120 and the first sealing member 2410, the filter may be configured to be smaller than the first sealing member 2410.
- the shape of the filter is changed. 1 It may be configured in a polygonal or star shape having vertices corresponding to the outer periphery of the sealing member 2410 .
- the first sealing member 2410 may be provided in a structure including a hole 2412 functioning as a passage of the coolant output through the first end of the perforation member 2200 .
- the first sealing member 2410 may be provided to have a structure including a hole 2412 in the central portion, and the hole 2412 of the first sealing member 2410 is formed at the first end of the perforation member 2200 . It may be formed in a structure capable of accommodating the coolant output through the filter or passing through the filter, and outputting the received coolant in the direction of the cooling device 1000 .
- the filter fixing module 2000 includes a second sealing member 2420 disposed on the opposite side of the direction in which the first sealing member 2410 is positioned with respect to the support surface 2120 of the body 2100 .
- the second sealing member 2420 is fitted into the body of the perforation member 2200, so that the first sealing member 2410 is positioned in the direction (eg, the first sealing member 2410) with respect to the support surface 2120 of the body 2100 .
- the first direction) may be disposed on the opposite side (eg, the second direction).
- the second sealing member 2420 may have a flat disk shape similar to that of the first sealing member 2410 and may be provided to be made of a material such as Teflon.
- the second sealing member 2420 may perform a function of reducing leakage of the coolant to be provided from the coolant supply unit 4000 to the hollow hole of the puncturing member 2200 to the outer surface of the puncturing member 2200 . Specifically, the second sealing member 2420 reduces the coolant discharged from the coolant supply unit 4000 and introduced into the second end of the perforation member 2200 from leaking to the outside through the outer surface of the perforation member 2200 . It can be provided to make
- the second sealing member 2420 may be provided in a structure including a through hole 2422 through which the body of the perforation member 2200 passes.
- the second sealing member 2420 may be provided to have a structure including a through-hole 2422 in the center, and the through-hole 2422 of the second sealing member 2420 is the body of the perforated member 2200. It may be provided in a size and shape to correspond to the diameter and shape of the body so that it can be fitted.
- the inner diameter of the second sealing member defined by the through hole 2422 of the second sealing member 2420 may be provided to be larger than the outer diameter of the body of the perforation member.
- the second sealing member 2420 may be configured together with the coolant supply unit 4000 .
- the second sealing member 2420 may be connected to the coolant supply unit 4000 and the adhesive through an adhesive or one end of the coolant supply unit 4000 . Through mechanical coupling through a shape corresponding to the shape of , it may be provided together with the coolant supply unit 4000 .
- the filter may have a shape corresponding to the filter fixing module 2000 so as to be well fixed in the filter fixing module 2000 .
- the filter may have a circular shape having a diameter corresponding to the inner diameter of the filter fixing module 2000 (eg, the inner diameter of the receiving surface 2140).
- the filter has a vertex inside the filter fixing module 2000, specifically the inner diameter of the receiving surface 2140, in order to improve the sealing effect by increasing the area in which the first sealing member 2410 is in close contact with the support surface 2120. It may be a polygon with a corresponding size. Alternatively, the filter may be provided in a star shape whose vertex corresponds to the inner diameter of the filter fixing module 2000 , specifically, the inner diameter of the receiving surface 2140 .
- the filter may be disposed on any path among the flow paths of the coolant in the filter fixing module 2000 .
- the filter may be positioned between the support surface 2120 of the body 2100 and the first sealing member 2410 .
- the filter may perform a function of filtering out impurities in the coolant included in the coolant that has passed through the hole of the first end of the perforating member 2200 and the body 2100 .
- the filter in order to increase the size of the contact surface between the first sealing member 2410 and the support surface 2120 , the filter may have a polygonal or star shape having a vertex meeting the outer periphery of the first sealing member 2410 .
- the filter fixing module 2000 having an arbitrary structure so that the filter can be positioned between the support surface 2120 of the body 2100 and the second sealing member 2420 may be provided.
- the structures of the components of the filter fixing module 2000 may be variously changed according to the arrangement position of the filter.
- the filter should not be construed as being included in the components of the filter fixing module 2000 disclosed herein. Therefore, even if any filter produced or distributed separately from the filter fixing module 2000 disclosed herein is used, it should be construed as belonging to the scope of the right of the filter fixing module 2000 disclosed herein.
- the receiving surface 2140 of the body 2100 may be provided to extend from the edge of the support surface 2120 to a first length L1 in the first direction. Meanwhile, the thickness of the first sealing member 2412 accommodated in the receiving surface 2140 may be provided to have a second length L2 along the first direction. In this case, the first length L1 and the second length L2 may be the same, but may be provided to have different lengths.
- the receiving surface 2140 and the first sealing member 2410 may be provided so that the second length L2 is greater than the first length L1 .
- the first sealing member 2410 may be accommodated in the receiving surface 2140 or to separate the accommodated first sealing member 2410 from the receiving surface 2140 .
- the perforation member 2200 has a first end adjacent to the support surface 2120 of the body 2100 , a second end supplied with the coolant discharged from the coolant supply unit 4000 , and a second end from the first end. It may include a body extending to two ends. In this case, the length of the body in the longitudinal direction (eg, the second direction) may be provided as the third length L3. In addition, the body of the perforation member 2200 may be provided to pass through the through hole 2422 of the second sealing member 2420 . In this case, the thickness of the second sealing member 2420 may be provided in the fourth length L4 along the second direction. In this case, the third length L3 and the fourth length L4 may be the same, but may be provided to have different lengths.
- the perforation member 2200 and the second sealing member 2420 may be provided so that the third length L3 is greater than the fourth length L4 .
- the perforation member 2200 penetrates the through hole 2422 of the second sealing member 2420 and the protruding excess body region perforates the coolant supply unit 4000 , and is drilled from the coolant supply unit 4000 .
- coolant flows into the second end of the member 2200, leakage of the coolant to be supplied from the coolant supply unit 4000 to the second end of the perforation member 2200 can be reduced by the second sealing member 2420.
- first and second grip members 2310 and 2320 may be provided with a fifth length L5 along the second direction.
- the third length L3 and the fifth length L5 that are the lengths of the body of the perforation member 2200 may be the same, but may be provided to have different lengths.
- the perforation member 2200 and the first and second grip members 2310 and 2320 may be provided so that the fifth length L5 is greater than the third length L3.
- the first and second grip members 2310 and 2320 may be provided so that the length of the first region P1 of the first and second grip members 2310 and 2320 is greater than the third length L3. have.
- the first and second grip members 2310 and 2320 may protrude outward than the coolant supply unit 4000 that is perforated by the perforation member 2200 . Accordingly, the user can easily apply force to the first and second grip members 2310 and 2320, and when the coolant supply unit 4000 is used, the filter fixing module 2000 can be more easily connected to the coupling member 1840. can be separated from
- the first sealing member 2410 may be provided to have a size and shape that can be accommodated in the receiving surface 2140 .
- the first sealing member 2410 may be provided to have a flat disk shape corresponding to the shape of the receiving surface 2140 , but to have a diameter that can be accommodated in the receiving surface 2140 .
- the first sealing member 2410 may be provided to have a diameter D1 smaller than a diameter D2 formed by the receiving surface 2140 .
- the first sealing member 2410 can be accommodated in the receiving surface 2140 and has a function of reducing the leakage of coolant flowing from the first end of the perforated member 2200 to the cooling device 1000 side. can be done efficiently.
- first sealing member 2410 and the accommodating surface 2140 shown in FIG. 16 are merely examples, and the first sealing member 2410 can be accommodated in the accommodating surface 2140 .
- the first sealing member 2410 and the receiving surface 2140 may be provided in an appropriate shape and size.
- FIG. 17 is a view illustrating an aspect in which the coolant supply unit 4000 is separated from the coupling member 1840 and the filter fixing module 2000 according to an embodiment of the present specification.
- the coolant supply unit 4000 is perforated by the perforation member 2200 of the filter fixing module 2000 and is screwed with the first screw structure 1842 of the coupling member 1840 . , it may be mounted on the cooling device 1000 . At this time, the user rotates the coolant supply unit 4000 during use of the cooling device 1000 or when the use of the cooling device 1000 is completed to form a first screw thread structure between the coolant supply unit 4000 and the coupling member 1840 ( 1842) can be separated.
- the thread of the coolant supply unit 4000 and the thread of the first thread structure 1842 of the coupling member 1840 mesh with each other, so that the coolant supply unit (4000) moves from the first direction to the second direction. Accordingly, the screw coupling between the screw line of the coolant supply unit 4000 and the screw line of the first screw line structure 1842 of the coupling member 1840 may be separated.
- the coolant supply unit 4000 when the coolant supply unit 4000 is rotated counterclockwise (or clockwise), the thread of the coolant supply unit 4000 and the thread of the first thread structure 1842 of the coupling member 1840 mesh with each other, so that the coolant supply unit (4000) moves from the first direction to the second direction. Accordingly, the coolant supply unit 4000 may be spaced apart from the perforation member 2200 . In other words, the coolant supply unit 4000 may be separated from the filter fixing module 2000 .
- the coolant in a gaseous state may remain in the coolant supply unit 4000 .
- the coolant may suddenly expand due to the difference between the internal pressure of the coolant supply unit 4000 and the atmospheric pressure, which may cause noise and inconvenience to users.
- the coolant supply unit 4000 disclosed herein when the coolant supply unit 4000 disclosed herein is separated from the coupling member 1840 , in particular, when the coolant supply unit 4000 starts to be separated from the perforation member 2200 of the filter fixing module 2000 , the coolant supply unit A space that can function as a fluid passage may be formed in the inner region of the coupling member 1840 between the 4000 and the filter fixing module 2000 .
- the gaseous coolant remaining in the coolant supply unit 4000 may be gradually discharged to the outside by using the area between the coolant supply unit 4000 and the filter fixing module 2000 as a fluid passage. Accordingly, according to the structures of the filter fixing module 2000 and the coolant supply unit 4000 disclosed herein, the Noise and user inconvenience can be minimized.
- the coolant supply unit 4000 By meshing the screw thread of the first screw thread structure 1842 of the coupling member 1840 with the screw thread of the first screw thread structure 1842 of the coupling member 1840 , the coolant supply unit 4000 may move from the second direction to the first direction. Accordingly, the screw thread of the coolant supply unit 4000 may be coupled to the coupling member 1840 through the screw connection with the first screw thread structure 1842 , and the coolant supply unit 4000 may be perforated by the perforation member 2200 .
- FIG. 18 is a view illustrating an aspect in which the filter fixing module 2000 is separated from the coupling member 1840 according to an embodiment of the present specification.
- the first grip member 2310 is fitted into the groove 1846a included in the thread 1842 of the coupling member 1840 and the second grip
- the member 2320 may be mounted to the coupling member 1840 by being fitted into the groove 1846b included in the thread 1842 of the coupling member 1840 .
- the user applies a force F1 to the first and second grip members 2310 and 2320 protruding to the outside during use of the cooling device 1000 or when the use of the cooling device 1000 is completed.
- the fixing module 2000 may be separated from the coupling member 1840 .
- the user applies a force F1 to the second region of the first and second grip members 2310 and 2320 protruding to the outside, so that the first and second grip members 2310 and 2320 are connected to the coupling member 1840. It can be separated from the grooves 1846a and 1846b included in the thread 1842 .
- the user applies a pulling force F1 to the first grip member 2310 and the second grip member 2320, thereby connecting the first and second grip members 2310 and 2320 to the coupling member 1840. It can be separated from the grooves 1846a and 1846b included in the thread 1842 .
- the user applies a force in a direction in which the first grip member 2310 and the second grip member 2320 come closer, thereby connecting the first and second grip members 2310 and 2320 to the coupling member 1840 . It can be separated from the grooves 1846a and 1846b included in the thread 1842 .
- first and second grip members 2310 and 2320 are connected to the coupling member 1840 of the coupling member 1840 .
- the force may be applied in any suitable direction to disengage from the grooves 1846a and 1846b included in the thread 1842 .
- the filter fixing module 4000 may include a first grip member 2310 and a second grip member 2320 protruding to the outside so that a user can easily apply a force. Accordingly, the filter fixing module 4000 according to an embodiment of the present specification can be easily separated from the coupling member 1840 even with a small force when use is completed.
- the filter fixing module including the body 2100 , the perforation member 2200 , the grip part 2300 and/or the sealing member 2400 . (2000) focused on the structure of the description.
- the structure of the components including the filter fixing module 2000 and the body 2100, the perforation member 2200, the grip part 2300 and/or the sealing member 2400 described in relation to FIGS. 9 to 18 is Just an example. Therefore, the structure of the filter fixing module 2000 and the body 2100, the perforation member 2200, the grip part 2300 and/or the sealing member 2400 shown in the present specification and drawings are limitedly interpreted. doesn't happen
- a cover accommodating the coolant supply unit 4000 may be provided outside the coolant supply unit 4000 .
- a screw thread or a coupling element may be present on the outer surface of the cover of the coolant supply unit 4000 .
- a screw line or a coupling element corresponding to a screw line or a coupling element formed on the outer surface of the cover of the coolant supply unit 4000 may be formed.
- the cover of the coolant supply unit 4000 may be coupled to the housing 1820 of the connection unit 1800 through screw coupling, etc., through which the coolant supply unit 4000 is accommodated inside the cover and the cooling device 1000 Of course, it can be configured in a form mounted on the.
- the cooling apparatus 1000 may spray the introduced coolant to the target area according to the coolant flow control of the coolant flow control unit 1100 .
- the cooling device 1000 may control the temperature of the coolant through the coolant temperature controller 1200 to spray the coolant to the target area.
- the cooling apparatus 1000 may be implemented to measure the temperature of the target area in real time, and to adjust the temperature of the coolant based on the temperature of the target area.
- the cooling device 1000 may obtain, through the input module 1500 , a user input for setting a cooling condition or a user input for instructing the start of a cooling operation.
- the cooling device 1000 may provide cooling information during cooling to the user through the output module 1600 .
- control module 1700 obtains an input related to a cooling condition from the input module 1500 or obtains an input for initiating a cooling operation of the cooling device 1000 to perform cooling corresponding to the input related to the cooling condition.
- the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 may be controlled.
- the control module 1700 may determine whether the sensor module 1400 is active by determining the normal operation of the sensor module 1400 .
- the cooling apparatus 1000 may include at least two or more temperature sensors.
- the cooling device 1000 may be implemented to determine whether at least two or more temperature sensors are operating normally by using at least two or more temperature sensors.
- the cooling apparatus 1000 according to an exemplary embodiment of the present specification can measure the temperature of the target area and prevent accidents such as overcooling of the target area due to a failure of the temperature sensor or the like in advance.
- 19 is a flowchart related to the operation of the control module 1700 for determining whether the sensor module 1400 operates normally according to an embodiment of the present specification.
- a method of determining whether the sensor module 1400 shown in FIG. 19 operates normally may be started when the cooling device 1000 is activated by a user input turning on a switch.
- the cooling device 1000 may be activated and may be started by additionally acquiring a user input for starting an operation for determining whether the sensor module 1400 operates normally.
- the control module 1700 may output, through the output module 1600 , information instructing the start of an operation for determining whether the sensor module 1400 is operating normally to the user. have.
- the user may instruct the initiation of an operation to determine whether the sensor module 1400 is operating normally through the input module 1500 , and the control module 1500 controls the normal operation of the sensor module 1400 in response to the user input. It may be implemented to initiate an operation of determining whether to operate.
- the method for determining whether the sensor module 1400 operates normally includes activating the first temperature sensor and the second temperature sensor ( S1100 ), the first temperature measured by the first temperature sensor Obtaining information and second temperature information measured by the second temperature sensor (S1200) and determining whether the difference between the first temperature information and the second temperature information is within a preset threshold (S1300) may include have.
- the method for determining whether the sensor module 1400 operates normally includes the step of deactivating at least one of the first temperature sensor and the second temperature sensor (S1400) or the first according to whether it is within a preset threshold value. It may be implemented to include the step of deactivating the temperature sensor and the second temperature sensor (S1500).
- the control module 1700 is a sensor module ( 1400) can be implemented.
- the sensor module 1400 may include at least two or more temperature sensors, as described above.
- the control module 1700 may control the sensor module 1400 to activate the first temperature sensor 1410 and the second temperature sensor 1420 of the sensor module 1400 .
- the sensor module 1400 controls a signal indicating that the first temperature sensor 1410 and the second temperature sensor 1420 are activated. may be transmitted to the module 1700 .
- FIG. 20 is a diagram illustrating an aspect of measuring first temperature information and second temperature information to determine whether the sensor module 1400 operates normally according to an embodiment of the present specification.
- control module 1700 when the first temperature sensor 1410 and the second temperature sensor 1420 are activated, through the output module 1600, the guide unit 1310, the temperature of the cradle (3000) Information indicating contact to the measurement region TD1 may be provided to the user.
- the first temperature sensor 1410 and the second temperature sensor 1420 measure the temperature of the temperature measurement region TD1, respectively. can be measured At this time, the sensor module 1400 obtains from the first temperature information T1 and the second temperature sensor 1420 related to the temperature of the temperature measurement region TD1 of the cradle 3000 obtained from the first temperature sensor 1410 . It may be implemented to transmit the second temperature information T2 related to the temperature of the temperature measurement region TD1 of the cradle 3000 to the control module 1700 .
- the control module 1700 performs the first temperature through the sensor module 1400
- the first temperature information T1 obtained from the sensor 1410 and the second temperature information T2 obtained from the second temperature sensor 1420 may be obtained.
- the control module 1700 performs the first temperature information T1 and the second temperature information obtained from the sensor module 1400 It is possible to determine whether the first temperature sensor 1410 and the second temperature sensor 1420 operate normally or the reliability of the first temperature information T1 and the second temperature information T2 based on the temperature information T2. have.
- the reliability of at least one of the first temperature information T1 and the second temperature information T2 is relatively low. This is high.
- the reliability of the first temperature information T1 and the second temperature information T2 is relatively high.
- control module 1700 determines the reliability of the first temperature information T1 and the second temperature information T2 or the first temperature sensor 1410 based on the first temperature information T1 and the second temperature information T2. ) and whether the second temperature sensor 1420 operates normally.
- control module 1700 controls the first temperature information T1 and the second temperature information T2 based on whether the difference between the first temperature information T1 and the second temperature information T2 is within a predetermined threshold value. The reliability of T2) can be judged.
- control module 1700 may be configured to calculate a difference value between the first temperature information and the second temperature information based on the first temperature information T1 and the second temperature information T2 .
- a threshold value may be preset in relation to a difference value between the first temperature information and the second temperature information.
- control module 1700 may determine whether the difference value between the first temperature information and the second temperature information is within a preset threshold value, and thus may control the subsequent operation of the cooling device 1000 . have.
- the reliability of at least one of the first temperature information T1 and the second temperature information T2 is relatively low. It could mean low.
- the relatively low reliability may mean that at least one of the first temperature sensor 1410 and the second temperature sensor 1420 is highly likely to not operate normally.
- any one of the measured first temperature information T1 and the second temperature information T2 has an error due to external factors, etc. It could mean that it happened.
- the control module 1700 controls the cooling device 1000 not to proceed with the subsequent cooling operation of the cooling device 1000 .
- the control module 1700 deactivates the first temperature sensor 1410 and the second temperature sensor 1420 if the difference value between the first temperature information and the second temperature information does not fall within a preset threshold (S1500). and end the cooling operation.
- the difference between the first temperature information and the second temperature information falls within a preset threshold value, it may mean that the reliability of the first temperature information T1 and the second temperature information T2 may be relatively high. .
- control module 1700 may be configured to subsequently perform the cooling operation of the cooling device 1000 .
- control module 1700 may be configured to deactivate ( S1400 ) at least one of the first temperature sensor 1410 and the second temperature sensor 1420 .
- deactivate S1400
- the first temperature sensor 1410 and the second temperature information T1 that have obtained the first temperature information T1 Since “at least one sensor” among the second temperature sensors 1420 that has obtained By deactivating the temperature sensor of the temperature sensor, the power required to measure the temperature of the temperature sensor can be saved.
- the first temperature information and the second temperature information may be measured in response to a user input instructing temperature measurement through the input module 1500 .
- the user uses the input module 1500 to provide the first temperature sensor 1410 and the second temperature sensor.
- the temperature measurement of 1420 may be indicated.
- the user may instruct the temperature measurement of the first temperature sensor 1410 and the second temperature sensor 1420 through the second input module 1520 located in the grip portion of the cooling device 1000 .
- the input for instructing the temperature measurement is a specific area for determining whether the first temperature sensor 1410 and the second temperature sensor 1420 operate normally (eg, the temperature measurement area TD1 of the cradle 3000 ). It may be associated with an input indicative of obtaining temperature information.
- FIG. 21 is a diagram illustrating an aspect in which the control module 1700 calculates a difference between first temperature information and second temperature information in order to determine whether the sensor module 1400 operates normally according to an embodiment of the present specification.
- the control module 1700 through the sensor module 1400, the first temperature information T1 related to the temperature of the temperature measuring region TD1 of the cradle 3000 obtained from the first temperature sensor 1410 and the second The second temperature information T2 related to the temperature of the temperature measurement region TD1 of the cradle 3000 obtained from the temperature sensor 1420 may be acquired.
- the first temperature sensor 1410 and the second temperature sensor 1420 may be activated.
- a switch button may be formed at the lower end of the cooling device 1000 illustrated in FIG. 20 .
- the first temperature sensor 1410 and the second temperature sensor 1420 may be activated.
- the first temperature sensor 1410 and the second temperature sensor 1420 may measure the temperature of the temperature measurement area or the like from the time when they are activated. Accordingly, the control module 1700 may determine whether the first temperature sensor 1410 and the second temperature sensor 1420 are normal based on the measured temperature at any time from the activated time.
- the control module 1700 may determine whether the first temperature sensor 1410 and the second temperature sensor 1420 are normal based on the measured temperature of the temperature measurement region TD1 after the user input is obtained. have.
- the control module 1700 may be configured to control the first temperature based on the first temperature information T1 and the second temperature information T2 at the point in time when an input instructing the measurement of the user's temperature through the input module 1500 is obtained. It may be implemented to calculate a difference between the information T1 and the second temperature information T2.
- control module 1700 may include the first temperature information T1 and the second temperature information at a time point when a preset time has elapsed from a point in time when an input instructing the measurement of a user's temperature through the input module 1500 is obtained. It may be implemented to calculate a difference between the first temperature information T1 and the second temperature information T2 based on (T2).
- control module 1700 to obtain temperature information at an appropriate time point or to determine whether the sensor module 1400 operates normally based on the temperature information. Of course, it can be implemented.
- the control module 1700 when both the first temperature sensor and the second temperature sensor are activated in step S1100, the control module 1700, through the output module 1600, the first temperature sensor 1410 and It may be configured to output information indicating that the second temperature sensor 1420 is activated to the user.
- the control module 1700, through the output module 1600, the first temperature sensor 1410 and the second temperature sensor 1420 are activated and to be configured to output information instructing the user to a subsequent operation to the user.
- control module 1700 may be configured to provide, through the output module 1600, information instructing the guide unit 1310 to contact the temperature measuring region T1 of the cradle 3000 to the user. .
- control module 1700 may provide the user with information indicating that the first temperature sensor 1410 and the second temperature sensor 1420 are activated through the output module 1600 for providing a notification sound.
- the control module 1700 performs the first temperature sensor 1410 and the second temperature sensor 1420 through the output module 1600 .
- the user may instruct the temperature measurement for determining whether the first temperature sensor 1410 and the second temperature sensor 1420 operate normally through the second input module 1520 . .
- control module 1700 transmits information instructing the setting of cooling time information and/or cooling temperature information to the user through the output module 1600 . can be printed to
- cooling time information and/or cooling time information and/or cooling temperature information in a visual form may be provided to the user with information related to initiating setting of the cooling temperature information.
- information related to starting the setting of cooling time information and/or cooling temperature information may be provided to the user in an auditory form through the speaker-type output module 1600 .
- the user may input cooling time information and/or cooling temperature information through the input module 1500 .
- the user may input cooling time information and/or cooling temperature information using the first input module 1510 in the form of a wheel switch shown in FIG. 24 . This will be described in detail with reference to FIGS. 23 to 24 .
- FIG. 22 is a diagram illustrating an aspect of measuring the temperature information of a target using at least one of the first temperature sensor 1410 and the second temperature sensor 1420 according to an embodiment of the present specification.
- the control module 1700 deactivates the second temperature sensor 1420 and is located closer to the target to more precisely measure the central temperature of the target. In order to do this, information on the temperature of the target measured from the first temperature sensor 1410 may be obtained.
- control module 1700 uses both the first temperature sensor 1410 and the second temperature sensor 1420 to control the subsequent cooling operation of the target area.
- the control module 1700 can be implemented to measure the temperature.
- 23 is a flowchart related to the operation of the control module 1700 for obtaining an input for initiating a cooling operation according to an embodiment of the present specification.
- 24 is a diagram illustrating at least one input module 1500 according to an embodiment of the present specification.
- 25 is a diagram illustrating an aspect of acquiring information related to a cooling condition through the first input module 1510 according to an embodiment of the present specification.
- the cooling conditions related to the cooling temperature and cooling time may vary depending on the type of treatment, the treatment site, and the like. Accordingly, the cooling apparatus 1000 according to an embodiment of the present specification may be implemented so that a user can set cooling conditions related to a cooling temperature, a cooling time, etc. according to a target treatment type.
- a method of obtaining an input for starting a cooling operation includes obtaining cooling temperature information and cooling time information (S2100) and obtaining a user input for starting a cooling operation (S2200) can do.
- the cooling device 1000 disclosed herein may include at least one input module.
- the cooling device 1000 includes one input module 1500 and the user inputs cooling time information and cooling temperature information by using a single input module 1500 to change the input type, or Initiation may be indicated.
- the cooling device 1000 may be implemented to differently acquire cooling time information and/or cooling temperature information by varying a time for a user to push a single input module 1500 .
- the cooling device 1000 may include a plurality of input modules 1500 .
- the cooling device 1000 may include the first input module 1510 positioned adjacent to the distal end of the gripper.
- the first input module 1510 may be provided in various forms as described above.
- the first input module 1510 may be configured in the form of a wheel switch, and the control module 1700 receives different information according to the user's rotation and push of the wheel switch with respect to the first input module 1510 . may be configured to obtain.
- the cooling device 1000 may include the second input module 1520 positioned at a portion where the user's finger is positioned according to the user's grip in the gripper.
- the second input module 1520 may be provided in various forms as described above.
- the second input module 1520 may be provided in the form of a button, and the control module 1700 instructs the start of the cooling operation based on a user's input pushing the second input module 1520 .
- an input instructing to measure the temperature of the temperature measurement region T1 may be acquired.
- cooling device 1000 includes a plurality of input modules 1500 , an intuitive input form may be provided to the user and user convenience may be increased.
- cooling conditions including cooling temperature information and cooling time information related information can be obtained.
- the first input module 1510 may be provided in the form of a wheel switch, as described above.
- the user may input information related to the cooling condition through an operation of rotating or pushing the wheel switch.
- cooling temperature information may be obtained.
- the user may set a high target temperature to control the target while rotating the first input module 1510 in the first direction.
- the user may set a low target temperature to control the target while rotating the first input module 1510 in the second direction.
- the output module 1600 may be configured to indicate to the user a change in cooling temperature information according to the rotation of the wheel switch. Meanwhile, by pushing the first input module 1510 , the user may complete the setting of cooling temperature information related to the target temperature to control the target.
- cooling time information may be obtained.
- the user may set a long cooling time while rotating the first input module 1510 in the first direction.
- the user may set the cooling time to be short while rotating the first input module 1510 in the second direction.
- the output module 1600 may be configured to indicate to the user a change in cooling time information according to the rotation of the wheel switch. Meanwhile, the user may complete the setting of cooling temperature information related to the cooling time by pushing the first input module 1510 .
- information related to the cooling condition may be obtained through various input devices using various methods other than the wheel switch.
- information related to the cooling condition may mean encompassing any suitable information related to the cooling operation other than the cooling temperature information and the cooling time information.
- control module 1700 may obtain the user's input for starting the cooling operation of the cooling device 1000 .
- control module 1700 may obtain a user input instructing the start of the cooling operation from the user through the second input module 1520 different from the first input module 1510 .
- the user may instruct the start of the cooling operation by pushing the button-shaped second input module 1520 .
- this is only an example, and a user input related to the start of the cooling operation may be obtained through various input devices using various methods other than a button.
- a mode for inputting cooling temperature information and cooling time information may be started, and the input module (eg, the first input An embodiment in which the user inputs cooling temperature information and cooling time information through the module 1510) and the cooling device 1000 cools the target area based on the set cooling temperature information and cooling time information has been mainly described.
- cooling device 1000 may be implemented to perform a cooling operation based on pre-stored cooling temperature information and cooling time information.
- control module 1700 starts the cooling operation by controlling the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 in response to a user input instructing the start of the cooling operation. can do.
- control module 1700 is configured to adjust the current applied to the coolant temperature controller 1200 based on the target temperature information and information related to the cooling condition including the obtained cooling temperature information and cooling time information.
- control module 1700 may control whether or not the coolant flow control unit 1100 is opened or closed, and the amount of cooling delivered to the target area may be controlled by adjusting the thermal energy applied to the coolant by the coolant temperature control unit 1200 . have.
- control module 1700 may adjust the amount of cooling delivered to the target area by adjusting whether the coolant flow control unit 1100 is opened or closed and the opening/closing time.
- control module 1700 controls whether the coolant flow control unit 1100 is opened or closed and the opening/closing time, and the amount of cooling delivered to the target area by adjusting the thermal energy applied by the coolant temperature control unit 1200 to the coolant. can be adjusted.
- control module 1700 controls the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 in more detail with reference to FIG. 26 .
- 26 is a flowchart illustrating a method in which the control module 1700 controls the coolant flow controller 1100 and/or the coolant temperature controller 1200 according to an embodiment of the present specification.
- the method for the control module 1700 to control the coolant flow controller 1100 and/or the coolant temperature controller 1200 is the coolant flow controller 1100 and/or the coolant temperature controller 1200 .
- the control module 1700 may be configured to activate (S3100) the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 in response to a user input related to initiating cooling with reference to FIG. 23 . have.
- control module 1700 may activate a valve of the coolant flow control unit 1100 in response to a user input for starting cooling. Specifically, the control module 1700 may activate the valve to open the valve of the coolant flow control unit 1100 . Also, the control module 1700 may be configured to control the opening/closing time of the valve of the coolant flow control unit 1100 based on the cooling time information set in relation to FIG. 23 .
- control module 1700 may activate the coolant temperature controller 1200 in response to a user input for starting cooling.
- control module 1700 may activate the first temperature control member 1221 and/or the second temperature control member 1222 of the coolant temperature control unit 1200 .
- control module 1700 includes a first temperature control member ( 1221) and/or a current value applied to the second temperature control member 1222 may be controlled.
- the control module 1700 may be configured to activate the sensor module 1400 in addition to the coolant flow control unit 1100 and the coolant temperature control unit 1200 in step S3100 .
- the control module 1700 may display the first temperature sensor 1410 and the second temperature sensor After deactivating all 1420 , it may be configured to activate at least one of the first temperature sensor 1410 and the second temperature sensor 1420 in step S3100 .
- the control module 1700 may obtain the temperature of the target measured from the sensor module 1400 .
- the temperature of the target may be measured through at least one of the first temperature sensor 1410 and the second temperature sensor 1420 of the sensor module 1400 .
- the sensor module 1400 may transmit the measured target temperature to the control module 1700 .
- the control module 1700 In the step (S3300) of controlling the current applied to the coolant temperature controller 1200, the control module 1700 based on the preset cooling temperature information obtained in relation to FIG. 23 and the measured temperature of the target obtained in step S3200 Thus, it may be configured to control the current applied to the coolant temperature control unit 1200 .
- the control module 1700 applies the first temperature control member 1221 and the second temperature control member 1222 of the coolant temperature control unit 1200 .
- the current value can be adjusted to be small. Through this, heat energy applied to the coolant from the first and second temperature control members 1221 and 1222 may be reduced, and the temperature of the coolant may be adjusted so that the temperature of the target approximates the preset cooling temperature.
- the control module 1700 controls the first temperature control member 1221 and the second temperature control member 1222 of the coolant temperature control unit 1200 .
- the control module 1700 can be adjusted to a high current value.
- the thermal energy applied to the coolant from the first and second temperature control members 1221 and 1222 may be increased, and the temperature of the coolant may be adjusted so that the temperature of the target approximates the preset cooling temperature.
- the control module 1700 determines whether the time at which the cooling operation is performed falls within the preset cooling time based on the preset cooling time information obtained in relation to FIG. 23 can be configured. To this end, the control module 1700 may be configured to additionally acquire time information and current time information of a time when the start of the cooling operation is started (eg, a time when a valve is opened, etc.).
- control module 1700 may determine that the cooling operation is within the preset cooling time.
- valve of the coolant flow control unit 1100 may be continuously activated and controlled so that the coolant is sprayed to the target.
- the control module 1700 obtains the measured temperature of the target through the sensor module 1400 ( S3200 ), based on the set cooling temperature information and the measured temperature of the target.
- the step of controlling the current applied to the coolant temperature controller 1200 (S3300) and the step of determining whether the current is applied within a set cooling time (S3400) may be repeatedly performed.
- control module 1700 may be implemented to determine that it does not correspond to the preset cooling time. In this case, the control module 1700 may be configured to end the cooling operation.
- control module 1700 may be configured to deactivate the valve of the coolant flow control unit 1100 .
- control module 1700 may be implemented to deactivate the coolant temperature controller 1200 .
- the control module 1700 controls the components of the cooling device 1000 (eg, the coolant flow control unit 1100 , the coolant temperature control unit 1200 , and the sensor module). 1400, etc.) to end the cooling operation.
- the components of the cooling device 1000 eg, the coolant flow control unit 1100 , the coolant temperature control unit 1200 , and the sensor module). 1400, etc.
- FIGS. 27 and 28 are flowchart illustrating a method in which the control module 1700 disclosed herein outputs a measured temperature of a target through the output module 1600 .
- 28 is a diagram illustrating an output of the temperature of the target measured through the output module 1600 disclosed herein.
- control module 1700 may obtain the measured temperature of the target from the sensor module 1400 in real time, and may provide the measured temperature of the target to the user through the output module 1600 in real time. .
- the method for the control module 1700 to output the measured temperature of the target includes the steps of obtaining the measured temperature of the target through the sensor module 1400 (S3200), and outputting the measured temperature of the target through the output module 1600 It may include a step (S3210) and a step (S3220) of determining whether it falls within the set cooling time.
- the control module 1700 is at least one of the first temperature sensor 1410 and the second temperature sensor 1420. It is possible to obtain the temperature of the target measured from the temperature sensor.
- step S3210 of outputting the measured temperature of the target through the output module 1600 the control module 1700 may transmit the measured temperature of the target obtained in step S3200 to the output module 1600 .
- control module 1700 may transmit the cooling temperature information obtained in relation to FIG. 23 to the output module 1600 .
- control module 1700 may transmit the cooling time information obtained in relation to FIG. 23 and the remaining cooling time information calculated based on the cooling execution time information to the output module 1600 .
- the cooling execution time information may be calculated based on time information at a time point when the cooling operation is started and current time information.
- the output module 1600 may output real-time temperature information of the target based on the received measured temperature of the target. Alternatively, the output module 1600 may output target temperature information of the target based on the received cooling temperature information. Alternatively, the output module 1600 may be configured to output the remaining cooling time information to the user based on the received remaining cooling time information.
- the output module 1600 may output real-time temperature information of the target and the target temperature of the target to the user.
- the user can intuitively check whether the cooling operation is normally performed by comparing the real-time temperature of the target with the target temperature of the target to be controlled. Accordingly, the cooling apparatus 1000 according to an embodiment of the present specification can safely implement a skin cooling procedure while preventing side effects due to overcooling of the target.
- the output module 1600 may output remaining cooling time information to the user.
- the user can immediately revise and supplement the cooling procedure plan by comparing the remaining cooling time with the procedure progress of the target.
- the cooling apparatus 1000 according to an embodiment of the present specification can implement a cooling procedure in which the effect of the procedure can be increased while preventing side effects caused by overcooling of the target.
- the content shown in FIG. 28 is merely an example for convenience of description, and any appropriate information may be processed and provided to the user through the output module 1600 .
- control module 1700 determines that, similar to step S3400 of FIG. 26 , the cooling operation is performed based on the preset cooling time information obtained in relation to FIG. 23 within the preset cooling time. It may be configured to determine whether
- control module 1700 may determine that the cooling operation is within the preset cooling time.
- the control module 1400 obtains the measured temperature of the target through the sensor module 1400 ( S3200 ), outputs the measured temperature of the target through the output module 1600 ( S3210 ), and the set cooling time It may be configured to repeatedly perform the step (S3220) of determining whether it falls within the That is, the control module 1400 may be configured to continuously acquire the measured temperature of the target and provide information on the measured temperature of the target to the user through the output module 1600 in real time.
- the control module 1700 may determine that it does not fall within the preset cooling time. In this case, the control module 1700 may be configured to end the cooling operation.
- the control module 1700 may be configured to deactivate the valve of the coolant flow control unit 1100 and also deactivate the coolant temperature control unit 1200 .
- the control module 1700 deactivates the components of the cooling device 1000 (eg, the coolant flow control unit 1100 , the coolant temperature control unit 1200 , the sensor module 1400 , etc.) to end the cooling operation. It can be configured to
- control module 1700 various control operations of the control module 1700 have been described. However, this is only an example, and any suitable method for controlling the temperature of the target to a target temperature may be implemented in order to minimize the side effects of the cooling procedure and to increase the cooling efficiency while being safe.
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Abstract
Description
Claims (31)
- 냉각재 공급부가 결합되도록 결합부를 가지는 핸드피스 냉각 장치에 장착되는 필터 고정 모듈에 있어서,판상으로 형성된 지지면 및 상기 지지면의 테두리에 형성되고, 상기 지지면을 기준으로 제1 방향으로 돌출되어 상기 지지면에 수용된 필터의 이탈을 방지하는 수용면을 가지는 몸체 및 상기 몸체와 연결되는 그립부를 포함하고,상기 그립부는 상기 몸체를 기준으로 상기 수용면이 돌출되는 방향과 반대측으로 연장되는 제1 그립부재 및 제2 그립부재를 포함하는,필터 고정 모듈.
- 제1 항에 있어서,상기 필터 고정 모듈은,상기 지지면을 기준으로 상기 제1 그립부재 및 상기 제2 그립부재와 동일한 측에 상기 지지면으로부터 돌출된 형상의 바디를 가지고, 상기 냉각재 공급부가 상기 결합부에 결합되면 상기 냉각재 공급부를 천공하는 천공부재를 포함하되,상기 바디는, 상기 냉각재 공급부로부터 유입되는 냉각재가 이동하도록 중공홀을 가지고, 상기 중공홀은 상기 냉각재 공급부로부터 유입되는 냉각재를 수용하는 제1 단부, 상기 지지면과 인접하며 냉각재를 상기 핸드피스 냉각 장치로 출력하는 제2 단부를 포함하는,필터 고정 모듈.
- 제2 항에 있어서,상기 제1 그립부재는 제2 방향으로 연장되는 제1-1 영역 및 상기 제2 방향과는 일정 각도를 가지는 제3 방향으로 연장되는 제2-1 영역을 포함하는 꺾인 평판 형상으로 마련되며,상기 제2 그립부재는 상기 제2 방향과 실질적으로 평행하게 연장되는 제1-1 영역 및 상기 제2 방향과는 일정 각도를 가지는 제4 방향으로 연장되는 제2-2 영역을 포함하는 꺾인 평판 형상으로 마련되며,상기 제1 그립부재의 상기 제1-1 영역과 상기 제2 그립부재의 상기 제1-2 영역은 서로 제1 거리만큼 이격되고 실질적으로 평행하되,상기 제1 그립부재의 상기 제2-1 영역과 상기 제2 그립부재의 상기 제2-2 영역의 최대 이격거리는 상기 제1 거리보다 큰,필터 고정 모듈.
- 제3 항에 있어서,상기 제1 그립부재의 상기 제2-1 영역 및 상기 제2 그립부재의 상기 제2-2 영역의 상기 지지면으로부터의 이격거리는, 상기 천공부재의 상기 제1 단부의 상기 지지면으로부터의 이격거리에 비해 큰,필터 고정 모듈.
- 제2 항에 있어서,상기 몸체와 상기 천공부재는 일체된 형상을 가지고,상기 천공부재의 제2 단부와 연결된 상기 지지면의 중심부에는, 상기 천공부재의 상기 제2 단부로부터 유입된 냉각재를 상기 수용면에 의해 수용된 상기 필터 측으로 출력하도록 구성된 연결홀이 형성되는,필터 고정 모듈.
- 제5 항에 있어서,상기 필터 고정 모듈은,상기 수용면 내에 적어도 일부 영역이 수용되도록 상기 수용면의 외경에 비해 작은 외경을 가지는 제1 실링부재를 더 포함하고,상기 제1 실링부재는 상기 지지면의 연결홀을 통과한 냉각재를 수용하여 상기 핸드피스 냉각 장치로 냉각재를 출력하도록 통로를 형성하는 중공홀을 포함하여, 상기 지지면과 상기 제1 실링부재의 접촉면을 통한 냉각재의 유출(leakage)을 감소시키는,필터 고정 모듈.
- 제6 항에 있어서,상기 지지면으로부터 돌출된 상기 수용면의 상기 제1 방향으로의 길이는, 상기 제1 실링부재의 두께보다 작아, 상기 수용면에 상기 제1 실링부재가 수용되면 상기 제1 실링부재의 적어도 일부 영역은 상기 수용면으로부터 외측으로 돌출되는,필터 고정 모듈.
- 제7 항에 있어서,상기 필터 고정 모듈은,관통홀을 가지고, 상기 냉각재 공급부로부터 상기 천공 부재의 중공홀로 제공될 냉각재가 상기 천공 부재의 외면으로 유출(leakage)되는 것을 감소시키는 제2 실링부재를 더 포함하고,상기 관통홀에 의해 정의되는 상기 제2 실링부재의 내경은 상기 천공부재의 외경에 비해 큰,필터 고정 모듈.
- 제8 항에 있어서,상기 천공부재의 상기 바디의 길이는 상기 제2 실링부재의 두께보다 길어, 상기 천공부재가 상기 제2 실링부재의 관통홀에 수용되면 상기 천공부재의 상기 제1 단부가 상기 제2 실링부재의 외측으로 돌출되는,필터 고정 모듈.
- 제6 항에 있어서,상기 제1 실링부재는 테프론(Teflon) 또는 Nylon 6(Nylon 6-6)의 물질로 구성되는,필터 고정 모듈.
- 제8 항에 있어서,상기 제2 실링부재는 테프론(Teflon) 또는 Nylon 6(Nylon 6-6)의 물질로 구성되는,필터 고정 모듈.
- 제8 항에 있어서,상기 필터는 상기 제1 실링부재와 상기 제2 실링부재 사이에 배치되도록 구성되는,필터 고정 모듈.
- 제8 항에 있어서,상기 필터는 상기 제1 실링부재와 상기 지지면 사이에 배치되도록 구성되는,필터 고정 모듈.
- 냉각재를 수용하는 냉각재 공급부로부터 유입되는 냉각재를 목표 영역에 분사하여 냉각을 수행하는 냉각 장치에 있어서,냉각재의 흐름을 조절하는 밸브;냉각재를 상기 목표 영역에 분사하는 노즐;상기 냉각재 공급부로부터 공급된 냉각재가 상기 밸브를 지나 상기 노즐을 통하여 분사되도록 유체의 이동 통로를 제공하는 관;상기 밸브, 상기 노즐 및 상기 관을 내부에 수용하는 본체;상기 제1 하우징과 결합되는 제1 나사선, 상기 냉각재 공급부와 결합되는 제2 나사선 및 상기 냉각재 공급부로부터 공급된 냉각재를 상기 관으로 유입시키도록 형성된 냉각재 이동홀을 포함하고, 상기 냉각재 공급부와 상기 관 사이에 위치되는 결합부재;판상으로 형성된 지지면, 상기 지지면의 테두리에 형성되고 상기 지지면을 기준으로 제1 방향으로 돌출되는 수용면을 가지는 몸체 및 상기 몸체와 연결되는 그립부를 포함하는 필터 고정 모듈을 포함하되, 상기 그립부는 상기 몸체를 기준으로 상기 수용면이 돌출되는 방향과 반대측으로 연장되는 제1 그립부재 및 제2 그립부재를 포함하고,상기 수용면에 필터가 배치된 상태로 상기 필터 고정 모듈이 상기 결합부재의 일 영역에 위치되면, 상기 필터에 의해 상기 냉각재 이동홀로 유입되는 냉각재의 불순물이 걸러지도록 상기 필터는 상기 지지면과 상기 냉각재 이동홀 사이에 배치되는,의료용 냉각 장치.
- 제14 항에 있어서,상기 제2 나사선은 적어도 두 홈 부재를 포함하되,상기 제1 그립부재 및 상기 제2 그립부재는 상기 적어도 두 홈 부재에 각각 끼워져 상기 필터 고정 모듈이 상기 결합부재에 연결되는,의료용 냉각 장치.
- 제15 항에 있어서,상기 제1 그립부재 및 상기 제2 그립부재가 상기 적어도 두 홈 부재에 각각 끼워진 상태에서 상기 제1 그립부재와 상기 제2 그립부재가 가까워지는 방향으로 힘이 인가된 경우, 상기 제1 그립부재 및 상기 제2 그립부재가 상기 적어도 두 홈 부재로부터 이탈되는,의료용 냉각 장치.
- 제14 항에 있어서,상기 결합부재 및 제1 하우징을 포함하는 연결부;를 더 포함하고,상기 제1 하우징은, 상기 본체의 외측면에 형성된 결합요소와 결합되는 제1 결합부 및 상기 결합부재의 외측면에 형성된 상기 제1 나사선과 결합되는 제2 결합부를 더 포함하는,의료용 냉각 장치.
- 제14 항에 있어서,상기 의료용 냉각 장치는,상기 밸브의 개폐 동작을 제어하는 제어 모듈을 더 포함하는,의료용 냉각 장치.
- 제14 항에 있어서,상기 필터 고정 모듈은, 상기 지지면을 기준으로 상기 제1 그립부재 및 상기 제2 그립부재와 동일한 측에 상기 지지면으로부터 돌출된 형상의 바디를 가지고, 상기 냉각재 공급부가 상기 제2 나사선에 결합되면 상기 냉각재 공급부를 천공하는 천공부재를 포함하되,상기 바디는, 상기 냉각재 공급부로부터 유입되는 냉각재가 이동하도록 중공홀을 가지고, 상기 중공홀은 상기 냉각재 공급부로부터 유입되는 냉각재를 수용하는 제1 단부, 상기 지지면과 인접하며 냉각재를 상기 관 방향으로 출력하는 제2 단부를 포함하는,의료용 냉각 장치.
- 제19 항에 있어서,상기 제1 그립부재는 제2 방향으로 연장되는 제1-1 영역 및 상기 제2 방향과는 일정 각도를 가지는 제3 방향으로 연장되는 제2-1 영역을 포함하는 꺾인 평판 형상으로 마련되며,상기 제2 그립부재는 상기 제2 방향과 실질적으로 평행하게 연장되는 제1-1 영역 및 상기 제2 방향과는 일정 각도를 가지는 제4 방향으로 연장되는 제2-2 영역을 포함하는 꺾인 평판 형상으로 마련되며,상기 제1 그립부재의 상기 제1-1 영역과 상기 제2 그립부재의 상기 제1-2 영역은 서로 제1 거리만큼 이격되고 실질적으로 평행하되,상기 제1 그립부재의 상기 제2-1 영역과 상기 제2 그립부재의 상기 제2-2 영역의 최대 이격거리는 상기 제1 거리보다 큰,의료용 냉각 장치.
- 제20 항에 있어서,상기 제1 그립부재의 상기 제2-1 영역 및 상기 제2 그립부재의 상기 제2-2 영역의 상기 지지면으로부터의 이격거리는, 상기 천공부재의 상기 제1 단부의 상기 지지면으로부터의 이격거리에 비해 큰,의료용 냉각장치.
- 제19 항에 있어서,상기 몸체와 상기 천공부재는 일체된 형상을 가지고,상기 천공부재의 제2 단부와 연결된 상기 지지면의 중심부에는, 상기 천공부재의 상기 제2 단부로부터 유입된 냉각재를 상기 수용면에 의해 수용된 상기 필터 측으로 출력하도록 구성된 연결홀이 형성되는,의료용 냉각 장치.
- 제22 항에 있어서,상기 필터 고정 모듈은,상기 수용면 내에 적어도 일부 영역이 수용되도록 상기 수용면의 외경에 비해 작은 외경을 가지는 제1 실링부재를 더 포함하고,상기 제1 실링부재는 상기 지지면의 연결홀을 통과한 냉각재를 수용하여, 상기 관 측으로 냉각재를 출력하도록 통로를 형성하는 중공홀을 포함하여, 상기 지지면과 상기 제1 실링부재의 접촉면을 통한 냉각재의 유출(leakage)을 감소시키는,의료용 냉각 장치.
- 제23 항에 있어서,상기 지지면으로부터 돌출된 상기 수용면의 상기 제1 방향으로의 길이는, 상기 제1 실링부재의 두께보다 작아, 상기 수용면에 상기 제1 실링부재가 수용되면 상기 제1 실링부재의 적어도 일부 영역은 상기 수용면으로부터 외측으로 돌출되어 상기 결합부재와 접촉하는,의료용 냉각 장치.
- 제24 항에 있어서,상기 필터 고정 모듈은,관통홀을 가지고, 상기 냉각재 공급부로부터 상기 천공 부재의 중공홀로 제공될 냉각재가 상기 천공 부재의 외면으로 유출(leakage)되는 것을 감소시키는 제2 실링부재를 더 포함하고,상기 제2 실링부재의 관통홀에 의해 정의되는 상기 제2 실링부재의 내경은 상기 천공부재의 외경에 비해 큰,의료용 냉각 장치.
- 제25 항에 있어서,상기 천공부재의 상기 바디의 길이는 상기 제2 실링부재의 두께보다 길어, 상기 천공부재가 상기 제2 실링부재의 관통홀에 수용되면 상기 천공부재의 제1 단부가 상기 제2 실링부재의 외측으로 돌출되어 상기 냉각재 공급부의 냉각재 방출구와 접촉하는,의료용 냉각 장치.
- 제23 항에 있어서,상기 제1 실링부재는 테프론(Teflon) 및 Nylon 6(Nylon 6-6)의 물질로 구성되는,의료용 냉각 장치.
- 제25 항에 있어서,상기 제2 실링부재는 테프론(Teflon) 및 Nylon 6(Nylon 6-6)의 물질로 구성되는,의료용 냉각 장치.
- 제25 항에 있어서,상기 필터는 상기 제1 실링부재와 상기 제2 실링부재 사이에 배치되도록 구성되는,의료용 냉각 장치.
- 제23 항에 있어서,상기 필터는 상기 제1 실링부재와 상기 지지면 사이에 배치되도록 구성되는,의료용 냉각 장치.
- 제20 항에 있어서,상기 제2 나사선은 적어도 두 홈 부재를 포함하며,상기 제1 그립부재의 제1-1 영역의 적어도 일부 영역은 상기 제2 방향으로 실질적으로 평행하게 형성된 상기 적어도 두 홈 부재 중 하나인 제1 홈 부재에 수용되고,상기 제2 그립부재의 제2-1 영역의 적어도 일부 영역은 상기 제2 방향과 실질적으로 평행하게 형성된 상기 적어도 두 홈 부재 중 하나인 제2 홈 부재에 수용됨으로써, 상기 필터 고정 모듈이 상기 결합부재에 장착되는,의료용 냉각 장치.
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EP4183378A4 (en) | 2023-12-06 |
US20230000666A1 (en) | 2023-01-05 |
EP4183378A1 (en) | 2023-05-24 |
JP2024079678A (ja) | 2024-06-11 |
JP2023533657A (ja) | 2023-08-04 |
KR102653459B1 (ko) | 2024-04-01 |
US11679024B2 (en) | 2023-06-20 |
KR20230078597A (ko) | 2023-06-02 |
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