KR20240051082A - Medical cooling system and medical cooling device using the same - Google Patents

Abstract

According to one embodiment of the present invention, it is a filter fixing module mounted on a handpiece cooling device having a coupling portion so that the coolant supply part is coupled, and is formed on a support surface formed in a plate shape and an edge of the support surface, and is based on the support surface. It includes a body having a receiving surface that protrudes in a first direction to prevent the filter accommodated in the support surface from being separated, and a grip part connected to the body, wherein the grip part is located on a side opposite to the direction in which the receiving surface protrudes with respect to the body. A filter fixing module may be provided, including a first grip member and a second grip member extending to.

Description

Medical cooling system and medical cooling device using the same {MEDICAL COOLING SYSTEM AND MEDICAL COOLING DEVICE USING THE SAME}

The present invention relates to a cooling system for cooling and a cooling device using the same, and more specifically, to a cooling device and a cooling method using a filter fixing module to easily detach and safely cool a target.

In modern society, in a social environment where skin diseases are increasing and interest in beauty culture is rapidly increasing, interest in skin treatments and skin care is rapidly increasing, and accordingly, Interest in and research on cooling devices is increasing.

Meanwhile, conventional cooling devices for skin procedures, especially cooling devices that cool the skin by spraying coolant onto the skin, use a coolant tank connected to the cooling device through a hose or use a coolant cartridge as a source of coolant. It has been used mounted on a cooling device.

However, the existing cooling device is not compatible with both the hose and coolant cartridge connected to the coolant tank, and was used separately as a cooling device for the coolant tank and a cooling device for the coolant cartridge.

Meanwhile, cooling devices for skin procedures may inevitably have safety issues in that they perform procedures on the skin. For example, impurities contained in the coolant may be delivered to the target area of the skin, causing skin infection.

Therefore, there is a need for research on the structure and control method of cooling devices that can perform cooling while increasing convenience of use and ensuring safety.

One problem that the present invention seeks to solve is to provide a filter fixing module for accommodating a filter that is mounted on a cooling device and filters out impurities in the coolant.

One problem that the present invention seeks to solve is to provide a cooling device in which a filter fixing module is mounted and separated.

The problem to be solved by the present invention is not limited to the above-mentioned problems, and problems not mentioned can be clearly understood by those skilled in the art from this specification and the attached drawings. .

According to one embodiment of the present specification, a filter fixing module mounted on a handpiece cooling device having a coupling portion for coupling the coolant supply portion is formed on a support surface formed in a flat plate shape in a first direction and an edge of the support surface, and the support surface A body having a receiving surface that protrudes in a second direction with respect to the surface to prevent the filter accommodated in the support surface from being separated - 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 the direction in which the receiving surface extends with respect to the body.

According to one embodiment of the present specification, a cooling device that performs cooling by spraying coolant flowing in from a coolant supply unit that accommodates coolant to a target area, comprising: a valve that regulates the flow of coolant; a nozzle that sprays coolant to the target area; a pipe providing a fluid movement passage so that the coolant supplied from the coolant supply unit passes through the valve and is injected through the nozzle; a main body accommodating the valve, the nozzle, and the pipe therein; It includes a first thread coupled to the first housing, a second thread coupled to the coolant supply unit, and a coolant moving hole formed to allow coolant supplied from the coolant supply unit to flow into the pipe, between the coolant supply unit and the pipe. A coupling member located at; A filter fixing module including a support surface formed in a plate shape, a body having a receiving surface formed on an edge of the support surface and protruding in a first direction with respect to the support surface, and a grip part connected to the body, wherein the grip part It includes a first grip member and a second grip member extending in a direction opposite to the direction in which the receiving surface protrudes with respect to the body, and with the filter disposed on the receiving surface, the filter fixing module is connected to the coupling member. When located in one area, the filter may be disposed between the support surface and the coolant transfer hole so that impurities of the coolant flowing into the coolant transfer hole are filtered by the filter.

The solution to the problem of the present invention is not limited to the above-mentioned solution, and the solution not mentioned can be clearly understood by those skilled in the art from this specification and the attached drawings. You will be able to.

According to an example of the present specification, the filter fixing module can be easily mounted and detached from the cooling device through the structure of the filter fixing module that protrudes to the outside of the cooling device.

According to an example of the present specification, when the filter fixing module is detached from the cooling device, a fluid passage through which the coolant can move is formed, which may cause inconvenience to the user due to expansion of the coolant.

The effects according to the present specification are not limited to the effects described above, and effects not mentioned can be clearly understood by those skilled in the art from this specification and the attached drawings.

Figure 1 is a diagram showing a cooling system 10 according to an embodiment of the present specification.
2 to 3 are diagrams showing a cooling system 10 according to an embodiment of the present specification. Specifically, FIG. 2 is a diagram showing the cooling system 10 using a cartridge as the coolant supply unit 4000, and FIG. 3 is a diagram showing the cooling system 10 using a coolant tank as the coolant supply unit 4000.
Figure 4 is a diagram 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 diagram showing a process of cooling a target through the cooling system 10 according to an embodiment of the present specification.
Figure 6 is a diagram showing the internal structure of the cooling device 1000 according to an embodiment of the present specification.
Figure 7 is a diagram showing the coolant temperature control unit 1200 according to an embodiment of the present specification.
FIG. 8 is a diagram showing a sensor module 1400 according to an embodiment of the present specification.
FIG. 9 is a diagram showing the internal structure of a cooling device 1000 equipped with a filter fixing module 2000 according to an embodiment of the present specification.
Figure 10 is an exploded view of a cooling device 1000 equipped with a filter fixing module 2000 according to an embodiment of the present specification.
Figure 11 is a perspective view of the coupling member 1840 on which the filter fixing module 2000 is mounted according to an embodiment of the present specification.
FIG. 12 is a diagram showing how the filter fixing module 2000 and the coupling member 1840 are coupled according to an embodiment of the present specification.
FIG. 13 is a diagram illustrating an aspect in which the coolant supply unit 4000 according to an embodiment of the present specification is screwed to the coupling member 1840 and perforated by the perforation member 2200 of the filter fixing module 2000.
Figure 14 is an exploded view of the filter fixing module 2000 according to an embodiment of the present specification.
FIG. 15 is a diagram illustrating the body 2100 and the grip portion 2300 of the filter fixing module 2000 according to an embodiment of the present specification.
FIG. 16 is a diagram illustrating the 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.
FIG. 17 is a diagram 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 diagram illustrating a state in which the filter fixing module 2000 is separated from the coupling member 1840 according to an embodiment of the present specification.
FIG. 19 is a flowchart related to the operation of the control module 1700 for determining whether the sensor module 1400 is operating normally according to an embodiment of the present specification.
FIG. 20 is a diagram showing an aspect of measuring first temperature information and second temperature information to determine whether the sensor module 1400 is operating normally according to an embodiment of the present specification.
FIG. 21 is a diagram showing how the control module 1700 calculates the difference between first temperature information and second temperature information to determine whether the sensor module 1400 is operating normally according to an embodiment of the present specification.
FIG. 22 is a diagram showing an aspect of measuring 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.
Figure 23 is a flowchart related to the operation of the control module 1700 for obtaining an input for starting a cooling operation according to an embodiment of the present specification.
Figure 24 is a diagram showing a plurality of input modules 1500 according to an embodiment of the present specification.
Figure 25 is a diagram showing an aspect of obtaining information related to cooling conditions through the input module 1510 according to an embodiment of the present specification.
Figure 26 is a flowchart showing how the control module 1700 controls the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 according to an embodiment of the present specification.
FIG. 27 is a flowchart showing how the control module 1700 disclosed in this specification outputs the measured temperature of the target through the output module 1600.
FIG. 28 is a diagram showing how the temperature of a target measured through the output module 1600 disclosed in this specification is output.

The above-described objects, features and advantages of the present application will become more apparent through the following detailed description in conjunction with the accompanying drawings. However, since the present application can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail below.

In the drawings, the thicknesses of layers and regions are exaggerated for clarity, and elements or layers are referred to as “on” or “on” other elements or layers. This includes not only those directly on top of other components or layers, but also cases where other layers or other components are interposed. Like reference numerals throughout the specification in principle refer to the same elements. In addition, components with the same function within the scope of the same idea shown in the drawings of each embodiment will be described using the same reference numerals, and overlapping descriptions thereof will be omitted.

If it is determined that a detailed description of a known function or configuration related to the present application may unnecessarily obscure the gist of the present application, the detailed description will be omitted. In addition, numbers (eg, first, second, etc.) used in the description of this specification are merely identifiers to distinguish one component from another component.

In addition, the suffixes “module” and “part” for components used in the following examples are given or used interchangeably only for the ease of writing the specification, and do not have distinct meanings or roles in themselves.

In the following examples, singular terms include plural terms unless the context clearly dictates otherwise.

In the following embodiments, terms such as 'include' or 'have' mean the presence of features or components described in the specification, and exclude in advance the possibility of adding one or more other features or components. It's not like that.

In the drawings, the sizes of components may be exaggerated or reduced for convenience of explanation. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, and the present invention is not necessarily limited to what is shown.

In cases where an embodiment can be implemented differently, a specific process sequence may be performed differently from the described sequence. For example, two processes described in succession may be performed substantially at the same time, or may be performed in an order opposite to that in which they are described.

In the following embodiments, when membranes, regions, components, etc. are connected, not only are the membranes, regions, and components directly connected, but also other membranes, regions, and components are interposed between the membranes, regions, and components. This includes cases where it is indirectly connected.

For example, in this specification, when membranes, regions, components, etc. are said to be electrically connected, not only are the membranes, regions, components, etc. directly electrically connected, but also other membranes, regions, components, etc. are interposed between them. This also includes cases of indirect electrical connection.

According to an embodiment of the present specification, a filter fixing module mounted on a handpiece cooling device having a coupling portion for coupling the coolant supply portion is formed on a support surface formed in a plate shape and an edge of the support surface, and is based on the support surface. It includes a body having a receiving surface that protrudes in a first direction to prevent the filter accommodated in the support surface from being separated, and a grip part connected to the body, wherein the grip part is located on a side 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.

According to one embodiment of the present specification, it includes a perforating member having a body of 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, wherein the perforation member When the coolant supply part is coupled to the coupling part, it has a hollow hole so that the coolant flowing from the coolant supply part moves, and the hollow hole has a first end for receiving the coolant flowing from the coolant supply part, the support surface and A filter holding module may be provided, adjacent thereto and including a second end outputting coolant to the handpiece cooling device.

According to one embodiment of the present specification, the first grip member includes a 1-1 area extending in a second direction and a 2-1 area extending in a third direction having a predetermined angle with the second direction. It is provided in a bent flat shape, and the second grip member includes a 1-1 region extending substantially parallel to the second direction and a 2-1 region extending in a fourth direction having a predetermined angle with the second direction. It is provided in a bent flat shape including two regions, wherein 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 are substantially parallel, A filter fixing module may be provided in which 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.

According to an embodiment of the present specification, the separation distance of the 2-1 region of the first grip member and the 2-2 region of the second grip member from the support surface is the distance between the first region of the perforation member and the 2-2 region of the first grip member. A filter fixing module may be provided that is large compared to the separation distance from the support surface at the end.

According to one embodiment of the present specification, the body and the perforation member have an integrated shape, and the coolant flowing in from the second end of the perforation member is located in the center of the support surface connected to the second end of the perforation member. A filter fixing module may be provided, in which a connection hole configured to output to the filter side accommodated by the receiving surface is formed.

According to one embodiment of the present specification, the filter fixing module further includes a first sealing member having a smaller outer diameter than the outer diameter of the receiving surface so that at least a portion of the area is accommodated within the receiving surface, and the first sealing member It includes a hollow hole that forms a passage to accommodate the coolant passing through the connection hole of the support surface and output the coolant to the handpiece cooling device, and the coolant flows out through the contact surface of the support surface and the first sealing member. A filter fixing module that reduces leakage may be provided.

According to one embodiment of the present specification, the length of the receiving surface protruding from the support surface in the first direction is smaller than the thickness of the first sealing member, so that when the first sealing member is received in the receiving surface, A filter fixing module may be provided in which at least a portion of the first sealing member protrudes outward from the receiving surface.

According to one embodiment of the present specification, the filter fixing module has a through hole and a second filter that reduces leakage of the coolant to be provided from the coolant supply unit to the hollow hole of the perforation member to the outer surface of the perforation member. A filter fixing module may be provided, further comprising a sealing member, and the inner diameter of the second sealing member defined by the through hole is larger than the outer diameter of the perforation member.

According to one embodiment of the present specification, the length of the body of the perforating member is longer than the thickness of the second sealing member, so that when the perforating member is received in the through hole of the second sealing member, the first part of the perforating member A filter fixing module may be provided, the end of which protrudes outward from the second sealing member.

According to an embodiment of the present specification, the first sealing member may be made of a plastic material or a rubber material, and more specifically, may be made of Teflon or Nylon 6 (Nylon 6-6), and is a filter fixing member. A module may be provided.

According to an embodiment of the present specification, the second sealing member may be made of a plastic material or a rubber material, and more specifically, a filter fixing module made of Teflon or Nylon 6 (Nylon 6-6). This can be provided.

According to one embodiment of the present specification, a filter fixing module may be provided in which the filter is configured to be disposed between the first sealing member and the second sealing member.

According to one embodiment of the present specification, the filter may be provided with a filter fixing module configured to be disposed between the first sealing member and the support surface.

According to another embodiment of the present specification, the filter fixing module may fix the first sealing member using an adhesive.

According to another embodiment of the present specification, the second sealing member may not be included in the filter fixing module, but may be provided as a coolant supply unit, and in this case, the second sealing member may have a shape that is mechanically coupled to the coolant supply unit. It may be provided or it may be provided together with a coolant supply unit through an adhesive.

According to an embodiment of the present specification, a cooling device that performs cooling by spraying coolant flowing in from a coolant supply unit that accommodates coolant to a target area, comprising: a valve that regulates the flow of coolant; a nozzle that sprays coolant to the target area; a pipe providing a fluid movement passage so that the coolant supplied from the coolant supply unit passes through the valve and is injected through the nozzle; a main body accommodating the valve, the nozzle, and the pipe therein; A first thread coupled to the first housing, a second thread coupled to the coolant supply unit, and a coolant moving hole formed to allow coolant supplied from the coolant supply unit to flow into the pipe, between the coolant supply unit and the pipe. A coupling member located at; A filter fixing module including a support surface formed in a plate shape, a body having a receiving surface formed on an edge of the support surface and protruding in a first direction with respect to the support surface, and a grip part connected to the body, wherein the grip part It includes a first grip member and a second grip member extending in a direction opposite to the direction in which the receiving surface protrudes with respect to the body, and with the filter disposed on the receiving surface, the filter fixing module is connected to the coupling member. When located in one area, a medical cooling device may be provided in which the filter is disposed between the support surface and the coolant movement hole so that impurities of the coolant flowing into the coolant movement hole are filtered by the filter.

According to one embodiment of the present specification, the second thread includes at least two groove members, and the first grip member and the second grip member are respectively inserted into the at least two groove members so that the filter fixing module is connected to the coupling member. can be connected to

According to one embodiment of the present specification, when the first grip member and the second grip member are respectively inserted into the at least two groove members, force is applied in a direction in which the first grip member and the second grip member approach each other. In this case, the first grip member and the second grip member may be separated from the at least two groove members.

According to an embodiment of the present specification, it further includes a connecting portion including the coupling member and the first housing, wherein the first housing includes a first coupling portion coupled to a coupling element formed on an outer surface of the main body, and the It may further include a second coupling part coupled to the first thread formed on the outer surface of the coupling member.

According to an embodiment of the present specification, the medical cooling device may further include a control module that controls the opening and closing operations of the valve.

According to an embodiment of the present specification, 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 When the supply part is coupled to the second thread, it includes a perforating member that perforates the coolant supply part, wherein the body has a hollow hole through which the coolant flowing from the coolant supply part moves, and the hollow hole allows the coolant flowing in from the coolant supply part to move. A medical cooling device may be provided, including a first end receiving coolant, a second end adjacent to the support surface and outputting coolant in the direction of the pipe.

According to one embodiment of the present specification, the first grip member includes a 1-1 area extending in a second direction and a 2-1 area extending in a third direction having a predetermined angle with the second direction. It is provided in a bent flat shape, and the second grip member includes a 1-1 region extending substantially parallel to the second direction and a 2-1 region extending in a fourth direction having a predetermined angle with the second direction. It is provided in a bent flat shape including two regions, wherein 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 are substantially parallel, A medical cooling device may be provided in which 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.

According to an embodiment of the present specification, the separation distance of the 2-1 region of the first grip member and the 2-2 region of the second grip member from the support surface is the distance between the first region of the perforation member and the 2-2 region of the first grip member. A medical cooling device can be provided that is large compared to the distance of the end from the support surface.

According to one embodiment of the present specification, the body and the perforation member have an integrated shape, and the coolant flowing in from the second end of the perforation member is located in the center of the support surface connected to the second end of the perforation member. A medical cooling device may be provided in which a connection hole configured to output the filter to the side accommodated by the receiving surface is formed.

According to one embodiment of the present specification, the filter fixing module further includes a first sealing member having a smaller outer diameter than the outer diameter of the receiving surface so that at least a portion of the area is accommodated within the receiving surface, and the first sealing member Includes a hollow hole that accommodates the coolant passing through the connection hole of the support surface and forms a passage to output the coolant to the tube side, and leakage of the coolant through the contact surface of the support surface and the first sealing member. ), a medical cooling device can be provided.

According to one embodiment of the present specification, the length of the receiving surface protruding from the support surface in the first direction is smaller than the thickness of the first sealing member, so that when the first sealing member is received in the receiving surface, A medical cooling device may be provided in which at least a portion of the first sealing member protrudes outward from the receiving surface and contacts the coupling member.

According to one embodiment of the present specification, the filter fixing module has a through hole and a second filter that reduces leakage of the coolant to be provided from the coolant supply unit to the hollow hole of the perforation member to the outer surface of the perforation member. A medical cooling device may be provided, further comprising a sealing member, wherein an inner diameter of the second sealing member defined by a through hole of the second sealing member is larger than an outer diameter of the perforation member.

According to one embodiment of the present specification, 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 received 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 discharge port of the coolant supply unit.

According to an embodiment of the present specification, the first sealing member may be made of a plastic material or a rubber material, and more specifically, may be made of Teflon or Nylon 6 (Nylon 6-6), and is a filter fixing member. A module may be provided.

According to an embodiment of the present specification, the second sealing member may be made of a plastic material or a rubber material, and more specifically, a filter fixing module made of Teflon or Nylon 6 (Nylon 6-6). This can be provided.

According to one embodiment of the present specification, a medical cooling device may be provided in which the filter is configured to be disposed between the first sealing member and the second sealing member.

According to one embodiment of the present specification, a medical cooling device may be provided in which the filter is configured to be disposed between the first sealing member and the support surface.

According to one embodiment of the present specification, the second thread includes at least two groove members, and at least a portion of the 1-1 region of the first grip member is formed substantially parallel to the second direction. A second groove member is received in a first groove member that is one of two groove members, and at least a portion of the 2-1 region of the second grip member is formed substantially parallel to the second direction. By being accommodated in the groove member, a medical cooling device can be provided in which the filter fixing module is mounted on the coupling member.

The present invention relates to a cooling system for cooling and a cooling device using the same, and more specifically, to a cooling device and a cooling method using a filter fixing module to easily detach and safely cool a target.

According to an embodiment of the present specification, the target can be cooled to a cool state using a cooling system for cosmetic or surgical procedures on the target, and at this time, a cooling control method may be used to prevent the target from being damaged due to reasons such as supercooling. You can.

The target may refer to an object to be cooled using a cooling system. For example, the target may refer to a target for skin beauty treatment using cooling. Specifically, the target is a part of the body that can be removed by cooling the local area, including moles, warts, corns, acne scars, etc., or a part of the body that requires local anesthesia during laser procedures such as hair removal, dermabrasion, and botox treatment. It can be included. For another example, the target may refer to an object to be put into an anesthetized or analgesic state in order to undergo a medical procedure. Specifically, the target may refer to a part of the body containing nerves, such as the diseased eye, skin, or gums.

Cooling means lowering the temperature of the target to be cooled by applying cooling energy to the target to be cooled and absorbing the heat energy of the target to be cooled. Here, cooling energy is used to express heat escaping by cooling, and can be understood as a concept to express a decrease in heat energy. For example, cooling may apply cooling energy to a target to be cooled by 'spraying' coolant or air gas onto the target. As another example, cooling can be performed by applying cooling energy to a target to be cooled by applying cooling energy to the target to be cooled by 'contacting' the cooling medium with the target to be cooled. In other words, it should be understood as a comprehensive concept that includes various methods of applying cooling energy to an object to be cooled. Hereinafter, for convenience of explanation, cooling the target through a non-contact method using a coolant will be described as a main embodiment, but the technical idea of the present specification is not limited to this.

The cooling system can also be used for treatment purposes such as alleviating inflammation (e.g., relieving acne), alleviating itching, removing pigmented lesions, vascular lesions, blemishes, and removing fat. Alternatively, the cooling system may cool the target and directly destroy at least part of the target. For example, if the target is a part of the body including the skin moles, warts, corns, etc. described above, the cooling system provides cooling energy to the target through the target surface, and the provided cooling energy causes the tissue within the target to become necrotic or die. can do. In another example, a cooling system may provide cooling energy by spraying coolant onto the target surface, and the provided cooling energy may be used to adjust the temperature of the nerves distributed beneath the target surface to a temperature at which the nerve is temporarily paralyzed or a temperature at which nerve transmission is blocked. By making it below, the target can be put into an anesthetized or pain-free state. The cooling system can cool the target surface and the target interior to an appropriate temperature range to produce this anesthetic or analgesic state for a certain period of time.

Hereinafter, for convenience of explanation, the main embodiment will describe a case where the target is the skin and coolant is sprayed on the skin surface in the cooling system to transfer cooling energy. However, the technical idea of the present specification is not limited to this and any body part. Of course, it can also be applied.

Hereinafter, the cooling system 10 according to an example of the present specification will be described with reference to FIGS. 1 to 4.

Figure 1 is a diagram showing a cooling system 10 according to an embodiment of the present specification. Referring to FIG. 1 , the cooling system 10 may include a cooling device 1000, a filter fixing module 2000, and a holder 3000.

The cooling device 1000 may cool the target by providing cooling energy to the target. Specifically, the cooling device 1000 can cool the target by delivering coolant at a target temperature to the target by adjusting the temperature of the coolant flowing through a passage within the cooling device, as will be described later.

The cooling device 1000 is connected to the filter fixing module 2000 and can filter out impurities contained in the coolant flowing in from the coolant supply unit 4000. Additionally, the cooling device 1000 can cool the target using coolant from which impurities have been filtered. 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 holder 3000 after or during use. For example, the cooling device 1000 may be mounted on the holder 3000 in an off state. For another example, the cooling device 1000 can be mounted on the holder 3000 according to the user's convenience while 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 can be mounted on the holder 3000. Specifically, 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 using the cooling device 1000.

As described later, the holder 3000 may include a temperature measurement area capable of measuring temperature to determine whether the operation of the sensor module 1400 of the cooling device 1000 is normal, and may protect the cooling device from external shock ( 1000) may have a shape to protect it. The temperature measurement area of the holder 3000 is described in detail in FIG. 20.

Meanwhile, in the cooling system 10 disclosed in this specification, the holder 3000 may be omitted.

2 to 3 are diagrams showing a cooling system 10 according to an embodiment of the present specification. Referring to FIGS. 2 and 3 , the cooling system 10 may include a cooling device 1000, a filter fixing module 2000, a holder 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.

The coolant supply unit 4000 may be composed of a cartridge containing a plurality of materials or may be composed of a plurality of cartridges in order to deliver materials other than the coolant to the target area.

Alternatively, the coolant supply unit 4000 may be in the form of a coolant tank. At this time, the coolant tank may be connected to a hose for supplying coolant to the cooling device 1000. At this time, the hose can supply the coolant contained in the coolant tank to the cooling device 1000 through a screw connection with the coupling member of the cooling device 1000.

Additionally, when the coolant supply unit 4000 is in the form of a coolant tank, the coolant tank and hose may be interpreted as meaning the coolant supply unit 4000.

Meanwhile, when the cooling device 1000 is connected to the coolant tank through a hose, the perforation member 2200 of the filter fixing module 2000 may be omitted.

Meanwhile, in order to deliver substances other than the coolant to the target area, the coolant supply unit 4000 may include a plurality of substances in a coolant tank or may be composed of a plurality of coolant tanks.

FIG. 4 is a diagram 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.

Referring to FIG. 4, 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.

Below, each configuration will be described in detail.

According to an embodiment of the present application, the coolant flow control unit 1100 may include a valve. The valve can perform the function of regulating the flow and rate of coolant. The valve may perform the function of leaking or blocking coolant passing through the valve. Alternatively, the valve may perform a function of controlling the degree of outflow of 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 perform opening and closing operations in response to an electronic signal generated by the control module 1700. As a specific example, the valve may be an electromagnetic valve (eg, solenoid valve), but is not limited thereto.

The valve according to an embodiment of the present application can be controlled according to the mechanical structure and movement of fluid. The valve may perform opening and closing operations depending on the pressure generated by the fluid moving along the flow path in the cooling device 1000. As a specific example, 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 can be controlled according to user input. The valve can be placed in an open or closed position by the user. As a specific example, the valve may be a manual valve (eg, globe valve), but is not limited thereto.

As an example, 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. At this time, the coolant flow control unit 1100 can control the amount of coolant supplied from the inlet of the cooling device 1000 to the nozzle unit 1300.

For example, the valve may be located between the inlet of the cooling device 1000 and the nozzle portion 1300 to control the amount of coolant supplied from the inlet of the cooling device 1000 to the nozzle portion 1300. Specifically, in the open state of the valve, the coolant can move from the inlet of the cooling device 1000 to the nozzle portion 1300, and in the closed state of the valve, the coolant can move from the inlet of the cooling device 1000 to the nozzle portion 1300. Movement may be restricted. Additionally, the amount of coolant that can be moved from the inlet of the cooling device 1000 to the nozzle unit 1300 can be adjusted by adjusting the opening time or opening cycle of the valve.

For example, the valve is located between the inlet of the cooling device 1000 located at the connection portion 1800 of the cooling device 1000 and the coolant temperature control unit 1200, and controls the coolant temperature at the inlet of the cooling device 1000. The amount of coolant supplied to the control unit 1200 can be adjusted. Specifically, in the open state of the valve, the coolant can be moved 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 is controlled by the coolant temperature in the inlet of the cooling device 1000. Movement to unit 1200 may be restricted. Additionally, the amount of coolant that can be moved from the inlet of the cooling device 1000 to the coolant temperature controller 1200 can be adjusted by adjusting the opening time or opening cycle of the valve.

As another example, the coolant flow control unit 1000 may be located between the coolant temperature control unit 1200 and the nozzle unit 1300 in the cooling device 1000. At this time, the coolant flow control unit 1100 can control the amount of coolant supplied from the coolant temperature control unit 1200 to the nozzle unit 1300. For example, the valve can be located 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. Specifically, in the open state of the valve, the coolant can move from the coolant temperature control unit 1200 to the nozzle unit 1300, and in the closed state of the valve, the coolant can move from the coolant temperature control unit 1200 to the nozzle unit 1300. Movement may be restricted. Additionally, the amount of coolant that can be moved from the coolant temperature control unit 1200 to the nozzle unit 1300 can be adjusted by adjusting the opening time or opening cycle of the valve. In other words, by adjusting the opening time of the coolant temperature control unit 1200, the amount of coolant supplied to the nozzle unit 1300 can be adjusted, and ultimately, the amount of coolant sprayed can be adjusted to control the temperature of the skin surface. You can.

As an example, 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, so that when the user operates the input module 1500, the solenoid valve is electrically connected to the control module 1700 and the input module 1500. The generated signal is input to the control module 1700, and the control module 1700 can control the inflow or outflow of coolant by controlling the solenoid valve to open based on this signal.

As an example, the coolant flow control unit 1100 may be implemented as a solenoid valve. In this case, the solenoid valve operates by pulse width modulation (PWM) according to the electrical signal from the control module 1700. An operation to control the inflow or outflow of coolant can be performed by adjusting the opening cycle. Specifically, the solenoid valve automatically performs a plurality of opening and closing operations according to a preset protocol from the control module 1700, allowing the valve to be opened only for a certain portion of the time during the procedure. At this time, the opening cycle of the valve may be a regular cycle or an irregular cycle.

Referring again to FIG. 4, the cooling device 1000 may include a coolant temperature controller 1200. The coolant temperature control unit 1200 according to an embodiment of the present application may perform the function of controlling the physical state of the coolant. In other words, the coolant temperature control unit 1200 may perform the function of controlling the physical state of the coolant in the cooling device 1000. That is, the coolant temperature control unit 1200 may perform the function of controlling the physical state of the coolant moving within the cooling device 1000.

As an example, the coolant temperature control unit 1200 can control the temperature of the coolant. The coolant temperature controller 1200 can heat the coolant. Alternatively, the coolant temperature controller 1200 may cool the coolant. Alternatively, the coolant temperature controller 1200 may maintain the temperature of the coolant by performing heating and/or cooling depending on the state of the coolant.

As an example, the coolant temperature control unit 1200 may be disposed between the coolant flow control unit 1100 and the nozzle unit 1300. As an example, the coolant temperature controller 1200 may be disposed between the coolant flow controller 1100 and the connection portion 1800. However, in order to maintain the temperature of the target at a constant temperature by spraying coolant on the target, it may be more advantageous for the coolant temperature control unit 1200 to be disposed between the coolant flow control unit 1100 and the nozzle unit 1300. .

The coolant temperature control unit 1200 according to an embodiment of the present application may include a temperature control member capable of generating heat energy.

The temperature control member may be implemented in various forms.

For example, the temperature control member may include a thermoelectric element that receives a current and uses the Peltier effect to absorb heat on one side and generate heat on the other side depending on the direction of the applied current. When the coolant temperature control unit 1200 includes a thermoelectric element, when current is applied to the thermoelectric element, the first side of the thermoelectric element generates heat energy and the second side of the thermoelectric element generates cooling energy due to the Peltier effect. can do.

According to an embodiment of the present application, a cooling device 1000 may be provided in which a surface corresponding to the first surface of the thermoelectric element is arranged to be in thermal contact with a passage moving the coolant, and at this time, the thermoelectric element is connected to the coolant. It can function as a temperature control unit 1200.

The coolant temperature controller 1200 may generate heat energy using chemical energy or generate heat energy using electrical energy. Additionally, the coolant temperature controller 1200 can generate heat energy using the Joule-Thomson method using condensed gas.

For example, the temperature control member is a device that uses a thermodynamic cycle such as a stirling cooler or a vapor compression refrigeration cycle, or a Houle-Thomson method using an expanding gas, or It may include elements.

As another example, the temperature control member may produce or provide cooling energy using a coolant such as carbon dioxide or liquid nitrogen.

The temperature control member may be thermally coupled to a passage through which coolant flows within the cooling device 1000. For example, the temperature control member may provide cooling energy or heat energy by making surface contact with at least a portion of the flow path through which the coolant flows.

Hereinafter, for convenience of explanation, the case where the temperature control member is a thermoelectric element using the Peltier effect will be mainly described, but the technical idea of the present specification is not limited to this.

Referring again to FIG. 4, the cooling device 1000 according to an embodiment of the present application may include a nozzle unit 1300. At this time, the nozzle unit 1300 may perform the function of spraying the coolant flowing inside the cooling device 1000 to the outside. The nozzle unit 1300 may perform the 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 according to an embodiment of the present application may be implemented as a nozzle of any appropriate shape. The nozzle may perform the function of spraying coolant flowing in at least one area within the cooling device 1000 so that the coolant is ejected into free space and reaches the target area on the skin surface. Additionally, the nozzle unit 1300 may be implemented to include a nozzle structure that can optimize the Joule-Thomson effect. Specifically, the nozzle is formed with a width narrower than the passage through which the high-pressure coolant flows. As the passage is opened, the high-pressure coolant is guided to the nozzle along the passage, and the coolant flowing out through the nozzle is reduced. -It can be implemented to spray in a cooled state through a nozzle due to the Thompson effect.

The coolant sprayed through the nozzle unit 1300 may be sprayed in a cooled state due to the Joule-Thomson effect. Here, the Joule-Thomson effect is a phenomenon in which the temperature drops when compressed gas expands. It is a phenomenon in which the temperature changes in relation to the thermodynamic phase consisting of pressure and temperature, and is applied when liquefying air or cooling through a refrigerant. This is a phenomenon in which the temperature of the fluid decreases behind the aperture when an aperture such as an orifice is inserted into the fluid flow path. When a gas free expands, that is, when it expands adiabatically without exchanging work with the outside, the internal energy is almost unchanged. This refers to the effect of adiabatic free expansion to obtain low temperature with a gas liquefaction device. Due to the Joule-Thomson effect, the coolant sprayed through the nozzle unit 1300 is cooled by a rapid pressure drop, and when the coolant is sprayed onto the treatment area, the coolant comes into contact with the treatment area and the coolant absorbs the heat of the treatment area. This may result in cooling of the treatment area.

Additionally, the nozzle may have wear-resistant properties. In other words, the nozzle can be made of a material that is less prone to friction damage. For example, the nozzle may be made of aluminum alloy, steel alloy, stainless steel, or copper alloy, but is not limited thereto.

In addition, according to an embodiment of the present application, the nozzle unit 1300 may further include a guide unit 1310 for defining an area where the coolant discharged from the nozzle unit 1300 reaches the skin surface.

Meanwhile, the guide unit 1310 may have a shape that can trap the coolant flowing laterally in a certain area after it is discharged from the nozzle unit 1300 and reaches the target area in the form of an impinged jet. For example, the surface that contacts the target area of the guide unit 1310 may be circular or polygonal, or may be circular or polygonal with discontinuous points.

At this time, the guide unit 1310 can evenly control the temperature of the target area by confining the coolant to a certain area, and after cooling the target area, the coolant can go out through a hole provided at the back.

Referring again to FIG. 4, the cooling device 1000 according to an embodiment of the present application may include a sensor module 1400. The sensor module 1400 may detect the temperature of a target area of the skin surface and/or the physical characteristics of the cooling device 1000.

As an example, the sensor module 1400 may detect the temperature of the target area. For example, 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 area 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 rays, thermocouples, resistance temperature detector (RTD), thermistor, IC temperature sensor, and ultrasonic waves. It may be composed of a contact-type temperature sensor such as a temperature sensor.

As another example, the sensor module 1400 may detect physical characteristics of components included in the cooling device 1000. For example, the sensor module 1400 can measure electrical characteristics such as current or voltage applied to the coolant temperature controller 1200. At this time, 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 the physical characteristics of the cooling device 1000 to the control module 1700. For example, the sensor module 1400 may provide a signal representing the real-time temperature value of the target area, the current or voltage value applied to the coolant temperature controller 1200, etc. to the control module 1700.

The input module 1500 may receive user input from the user. User input can take many forms, including button input, key input, touch input, rotation input, or voice input. For example, the input module 1500 may include a button that the user can press, a wheel switch that the user can rotate, a touch sensor that detects the user's touch, a microphone that receives the user's voice input, and various other types of user input. It is a comprehensive concept that includes all various types of input means that sense or receive input.

The output module 1600 can output various information and provide it to the user. The output module 1600 includes a display that outputs information related to the cooling status of the cooling device and the real-time temperature of the target area, a speaker that outputs sound, a haptic device that generates vibration, and various other types of output means. It is a comprehensive concept that includes

The control module 1700 can control the overall operation of the cooling device 1000. For example, the control module 1700 may load and execute a program for operating the coolant flow control unit 1100. For another example, the control module 1700 controls the amount of current (or voltage) applied to the coolant temperature controller 1200 to adjust the heat energy delivered to the coolant or the input module 1500 and output module 1600. ) can be controlled to generate and transmit control signals according to user input or provide specific information to the user.

Here, the control module 1700 may include a central processing unit (CPU), a microprocessor, a processor core, a multiprocessor, or an application integrated circuit (ASIC), depending on hardware, software, or a combination thereof. - It can be implemented with devices such as integrated specific circuit) and FPGA (field programmable gate array). 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, or may be provided in the form of a program or code that drives the hardware circuit in software.

Meanwhile, although not shown in FIG. 4, the cooling device 1000 further includes a memory that stores control programs loaded or executed in the control module 1700, and a power supply unit that supplies power necessary for the operation of the cooling device 1000. can do.

The connection part 1800 may be provided in a structure that connects the coolant supply part 4000 and the cooling device 1000.

Specifically, the connection part 1800 may include a housing 1820 for accommodating at least a portion of the coolant supply part 4000 and/or the filter fixing module 2000.

Additionally, the connection part 1800 may include a coupling member 1840 for mounting the coolant supply part 4000 and/or the filter fixing module 2000.

As an example, the coupling member 1840 may be provided in a structure including threads. For example, the coupling member 1840 may be a member including a thread composed of a thread and a thread bone. Here, the thread of the coupling member 1840 is screwed to the thread of the coolant supply unit 4000, so that the coolant supply unit 4000 and the cooling device 1000 can be connected.

As an example, the coupling member 1840 may include a thread structure including at least one groove. For example, a filter fixing module 2000, which will be described later, may be disposed between the connection part 1800 and the coolant supply part 4000 of the cooling device 1000. The filter fixing module 2000 may include a grip portion 2300, and the thread of the coupling member 1840 may include a groove formed in a shape corresponding to the shape of the grip portion.

At this time, the coolant supply part 4000 is perforated by the perforation member 2200 of the filter fixing module 2000, and the grip part 2300 of the filter fixing module 2000 can be fitted into the groove of the coupling member 1840. Through the connection structure, the coolant discharged from the coolant supply part 4000 can flow into the cooling device 1000 through the connection part 1800.

Through the structure of the connection part 1800 described above, the filter fixing module 2000 according to an embodiment of the present specification can be accommodated in the coupling member 1840 of the connection part 1800, and the coolant supply part 4000 is connected to the connection part 1800. It can be drilled 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 not only performs the function of perforating the coolant supply part 4000, but also performs the function of accommodating the filter on the path through which the coolant flows. . In addition, the filter fixing module 2000 may include a grip portion 2300 protruding outward from the connection portion 1800 for ease of use, through which the user can attach the filter fixing module 2000 to the cooling device 1000. It can be easily mounted or removed. This will be described in more detail later with reference to FIGS. 9 to 18.

The filter fixing module 2000 may include a body 2100, a perforation member 2200, a grip portion 2300, and a sealing member 2400.

Body 2100 may have a support surface that supports the filter. Additionally, the body 2100 may accommodate 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 that allow the filter to be positioned within the filter fixing module 2000.

Additionally, the filter fixing module 2000 may be located between the coolant supply unit 4000 and the cooling device 1000, and may be positioned along the path through which the coolant discharged from the coolant supply unit 4000 flows into the inlet of the cooling device 1000. A filter can be placed in . Accordingly, the coolant may be introduced into the cooling device 1000 through the filter fixing module 2000 after impurities contained in the coolant are removed. Accordingly, the cooling system 10 according to an embodiment of the present application can be provided to minimize the possibility that the target area is contaminated by impurities contained in the coolant.

The perforation member 2200 may have a body in which hollow holes are formed to function as a flow path for coolant discharged from the coolant supply unit 4000. The perforating member 2200 may have a first end adjacent to the support surface of the body 2100, a second end perforating the coolant outlet of the coolant supply unit 4000, and a body extending from the first end to the second end. . At this time, the perforating member 2200 may receive 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 thread of the coupling member 1840.

For example, the grip portion 2300 may include two grip members 2310 and 2320. At this time, 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.

For example, the grip unit 2300 may include four grip members. At this time, 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.

At this time, the above-described grip member and the threaded groove member of the coupling member 1840 may be formed in a symmetrical structure with respect to the central axis. Alternatively, the threaded groove member of the grip member and the coupling member 1840 described above may be formed in an asymmetrical structure with respect to the central axis.

Through the above-described structure, the filter fixing module 2000 can be mounted on the connection portion 1800 of the cooling device 1000.

However, the above-described structure is only an example, and the grip portion 2300 may be provided in various structures that can be connected to the coupling member 1840.

With at least one grip member (2310 or 2320) mounted on the connection portion 1800 of the cooling device 1000, at least one grip member (2310 or 2320) may be provided to protrude out of the cooling device 1000. there is. Accordingly, the user can easily apply force to 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 removed from the groove member formed on the thread of. For example, when the user applies force in a direction in which at least one grip member 2310 or 2320 approaches each other, at least one grip member 2310 or 2320 deviates from the groove member formed on the thread of the coupling member 1840. It can be.

Through the above-described structure, when the use of the coolant supply unit 4000 (e.g., cartridge or coolant tank) is completed, the user cools the filter fixing module 2000 by applying force to at least one grip member 2310 or 2320. It can be easily detached from the device 1000.

Meanwhile, when the use of the coolant supply unit 4000 (eg, cartridge or coolant tank) is completed, at least gaseous coolant may remain in the coolant supply unit. When gaseous coolant is exposed to atmospheric pressure, it expands momentarily, causing noise and inconvenience to users.

According to the cooling system 10 according to an embodiment of the present application, as described above, when use of the coolant supply unit 4000 is completed, the user can separate the coolant supply unit 4000 from the coupling member 1840. . For example, the user may rotate the cartridge-shaped coolant supply unit 4000 in one direction so that the screw connection between the thread of the cartridge and the thread of the coupling member 1840 is separated. At this time, as the coolant supply unit 4000 is separated from the coupling member 1840, a fluid passage may be formed inside the coupling member 1840. At this time, the gaseous coolant remaining in the coolant supply unit 4000 (e.g., cartridge or coolant tank) leaks through the fluid passage, thereby minimizing user inconvenience that may occur due to exposure of the gaseous coolant to atmospheric pressure. It can be.

Meanwhile, the user may apply force to 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 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.

At this time, the filter fixing module 2000 includes a first sealing member 2410 accommodated in a receiving surface extending in a first direction with respect to the body 2100 and a second direction opposite to the first direction with respect to the body. The extended perforation member 2200 may include a second sealing member 2420 penetrating therethrough.

The first sealing member 2410 may perform a function of reducing leakage of coolant flowing from the filter fixing module 2000 to the cooling device 1000.

The second sealing member 2420 functions to reduce 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.

Meanwhile, the first sealing member 2410 may include a hollow hole through which coolant can flow. For example, a hollow hole forming a passage through which coolant can 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 perforating member 2200 can pass. For example, 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. there is. For example, the inner diameter of the second sealing member 2420 defined by the through hole may be larger than the outer diameter of the perforating member 2200.

The filter fixing module 2000 according to an embodiment of the present application is compatible with both the cartridge-type coolant supply unit 4000 or the coolant tank-type coolant supply unit 4000. For example, the perforating member 2200 of the filter fixing module 2000 may be provided to perforate a hose connected to a cartridge or coolant tank.

The structure and shape of the filter fixing module 2000 will be described in detail later with reference to FIGS. 9 to 18.

Below, with reference to FIG. 5 , a process in which the cooling system 10 according to an embodiment of the present specification performs cooling on a target will be described in detail.

FIG. 5 is a diagram showing a process of cooling a target through the cooling system 10 according to an embodiment of the present specification.

The control module 1700 may control whether to spray coolant introduced into the cooling device 1000 through the coolant movement hole formed inside the connection portion 1800 and/or the amount of coolant to be sprayed.

For example, the control module 1800 can control whether coolant is sprayed and/or the amount of coolant sprayed by controlling the coolant flow control unit 1100.

Additionally, the control module 1700 can control the temperature of the coolant flowing inside the cooling device 1000 by controlling the coolant temperature controller 1200. Through this, the cooling device 1000 can cool the target by spraying coolant with controlled temperature characteristics to the target on the skin surface through the nozzle unit 1300 and providing cooling energy to the target.

Below, the process in which the cooling function is performed is described in detail.

The control module 1700 provides heat energy to the coolant flowing through the pipe of the coolant temperature control unit 1200 by controlling the temperature control member of the coolant temperature control unit 1200, so that the temperature of the coolant can be adjusted to a preset temperature. . For example, 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, decrease or maintain the heat energy applied to the coolant. can do. In addition, the cooling system 10 according to an embodiment of the present application can ultimately 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, which changes as cooling energy by the coolant is transmitted to the target, and transmit the obtained temperature information to the control module 1700.

Meanwhile, the temperature information acquired by the sensor module 1400 is information about the temperature of components within the cooling device 1000 (e.g., the temperature of the temperature control member of the coolant temperature control unit 1200, etc.) or information about the temperature of the cooling device 1000. It may further include information about the surrounding temperature. Here, the sensor module 1400 may include a plurality of sensors to obtain 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.

As an example, the control module 1700 can use feedback control to control 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. there is. Specifically, the control module 1700 can control the temperature of the target using the Proportional Integral Differential (PID) control equation below.

Here, P(t) refers to the output value or control value of the signal through which the control module 1700 controls the temperature control member, and error(t) refers to the temperature of the target that the control module 1700 wants to control and the sensor module. This refers to the temperature difference value of the target measured at 1400, and Cp, Ci, and Cd may refer to gain values or gains selected during the tuning process. Meanwhile, of course, each term can be omitted from the above control equation and P, PI, and PD control can be used.

As another example, the control module 1700 provides power corresponding to the 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 control unit 1200 and the coolant flow path, etc. Can be provided to the temperature control member.

The input module 1500 may obtain user input for setting cooling time, target control temperature (or coolant control temperature), etc. For example, the user can preset the time at which the coolant is sprayed onto the target by setting the coolant injection time through the input module 1500. For another example, the user may preset the temperature of the target to be controlled through the input module 1500.

The input module 1500, which obtains 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 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 and opening/closing time of the valve of the coolant flow control unit 1100 can be controlled.

Meanwhile, the input module 1500 may obtain an input indicating the start of cooling in addition to input information related to cooling conditions including cooling time and target control temperature. For example, when the input information related to the above-described cooling conditions is completed, the user may input an input indicating the start of cooling through the input module 1500. At this time, the input module 1500 may be implemented to transmit an input signal indicating the start of cooling to the control module 1700, and the control module 1700 controls the coolant flow in response to the user's input indicating the start of cooling. It may be implemented to control the opening and closing of the valve of the control unit 1100 or to adjust the current (or voltage) value applied to the temperature control member of the coolant temperature control unit 1200.

At this time, input information related to cooling conditions and input information indicating the start of cooling may be configured to be acquired through different input modules 1500. For example, input information related to cooling conditions is obtained through the first input module 1510, but input information related to cooling conditions is implemented to be obtained from a second input module 1520 that is separate from the first input module 1510. It can be.

However, the above is only an example, and is not limited thereto, and an input module may be provided to obtain input information related to cooling conditions and input information indicating the start of cooling through a single input module.

Operations related to the input module will be described in detail later in FIGS. 20 and 21.

The output module 1600 can output various information related to the cooling device 1000 and provide it to the user.

For example, the output module 1600 may output real-time temperature information of the target area through a display. Specifically, the sensor module 1400 can measure temperature information of the target and transmit the measured temperature information of the target to the control module 1700. At this time, the control module 1700 may transmit temperature information of the target to the output module 1600, and the output module 1600 may be configured to output temperature information of the target area based on the acquired temperature information of the target.

The output module 1600 may output information related to the status of the cooling device 1000 and provide it to the user.

For example, the control module 1700 determines whether the first temperature sensor 1410 and the second temperature sensor 1420 are normal based on temperature information obtained from the first temperature sensor 1410 and the second temperature sensor 1420. You can judge. At this time, the control module 1700 may provide a determination result regarding 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 are operating normally, the first alarm is output through the speaker-shaped output module 1600, 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 if it is not determined that it is operating normally.

However, the above is only an example, and any appropriate information related to the operation of the cooling device 1000 may be provided to the user through any type of output module 1600.

Operations related to the output module 1600 will be described in detail later with reference to FIGS. 27 to 28.

Below, the structure of the cooling device 1000 will be described with reference to FIGS. 6 to 8.

Figure 6 is a diagram showing the internal structure of the cooling device 1000 according to an embodiment of the present specification. Referring to FIG. 6, the cooling device 1000 may include a main body composed of a body portion and a grip portion, and the components of the cooling device 1000 described above may be disposed in the body portion or the grip portion.

The main body of the cooling device 1000 can be divided into a body part and a grip part. For example, the main body of the cooling device 1000 may include a body portion on which the filter fixing module 2000 and the coolant supply portion 4000 are mounted, and a grip portion that can be held by the user. Here, the body portion and the grip portion may be implemented as one piece, or may be physically separated but combined through assembly to form 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 portion. Specifically, 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 are installed inside the body unit around the central axis (CA) of the body unit. can be placed. For example, 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, and the coolant flow control unit 1100 and the connection unit 1800 are located at the front end (F) of the body. It can be placed close to the rear end (R).

Meanwhile, an input module 1500 and an output module 1600 may be additionally disposed in the body portion. At this time, the input module 1500 includes a plurality of input devices and may be disposed close to the front end (F) or rear end (R) of the body, respectively. Additionally, the output module 1600 includes a plurality of output devices and may be disposed close to the front end (F) or rear end (R) of the body, respectively.

Here, 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.

Here, the connection part 1800 may constitute at least a portion of the main body. For example, the connection portion 1800 may be formed at the rear end (R) of the body portion of the cooling device 1000. Alternatively, the connection part 1800 may be implemented as being coupled to the body part.

Here, the filter fixing module 2000 may be mounted on the main body. For example, the grip members 2310 and 2320 of the filter fixing module 2000 may be mounted on or separated from the cooling device 1000 at the rear end (R) of the body portion. For example, the grip members 2310 and 2320 may be mounted on or separated from the cooling device 1000 through the connection portion 1800 formed at the rear end (R) of the body portion. Specifically, the grip members 2310 and 2320 may be mounted on or separated from the cooling device 1000 through at least one groove formed in the thread of the connection portion 1800 formed at the rear end of the body portion.

A control module 1700 may be disposed inside the gripper. For example, referring again to FIG. 6, the control module 1700 may be disposed inside the gripper along the longitudinal direction of the gripper.

Additionally, the input module 1500 may be disposed inside or outside the gripper.

For example, an input module 1500, such as a button for instructing to start cooling, may be placed at the part of the gripper where the user's fingers are located according to the user's grip. 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.

For another example, an input module 1500 such as a wheel switch or button for setting cooling conditions such as cooling time and target control temperature may be disposed outside the gripper (e.g., outside the end of the gripper). there is. Therefore, the user can easily set cooling conditions, etc. before starting cooling.

Additionally, the output module 1600 may be disposed inside or outside the gripper.

For example, when using the cooling device 1000, the state of the cooling operation (e.g., temperature information of the target and remaining time of the cooling operation, etc. ), an output module 1600 such as a display 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.

Furthermore, the holding part is equipped with any suitable heating member and charger, such as a switch for controlling whether the cooling device operates, a power supply unit for supplying power to the cooling device 1000, and a blower for dissipating heat generated from the power supply unit. Ports, etc. may be placed.

Meanwhile, the arrangement of the components of the cooling device 1000 within the body portion and the grip portion of the cooling device 1000 is not limited to the above-described contents.

Figure 7 is a diagram showing the coolant temperature control unit 1200 according to an embodiment of the present specification.

Referring to FIG. 7, the coolant temperature control unit 1200 may include a temperature control member 1220, a porous member 1240, an insulation member 1260, and a tube.

The tube may be thermally coupled to the temperature control member 1220. For example, 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 heat energy from the first and second temperature control members 1221 and 1222 through the first and second surfaces. At this time, the pipe shown in FIG. 7 may be a single pipe from the pipe in which the inlet 1110 shown in FIG. 10 is formed. Alternatively, the pipe shown in FIG. 7 may be a separate pipe from the pipe in which the inlet 1110 shown in FIG. 10 is formed, but may be pipes connected to each other.

At this time, the tube and temperature control member 1220 may be configured in a shape to efficiently transfer heat energy or cooling energy. For example, at least a portion of the tube and the temperature control member 1220 may be implemented in a rectangular parallelepiped shape to make surface contact. Meanwhile, the shape of the tube and temperature control member 12200 is not limited to the above-described rectangular parallelepiped and can be implemented in various shapes for surface contact.

Additionally, the first temperature control member 1221 and the second temperature control member 1222 may be fixed to the pipe in surface contact.

Here, the temperature control member 1220 may include one side and the other side that absorbs heat or generates heat depending on the direction of the applied current. At this time, preferably, one side of the temperature control member 1220 in contact with the pipe may be configured as a side that generates heat according to the direction of the applied current, and the other side of the temperature control member 1220 is a side that absorbs heat and provides thermal energy to the pipe. It can be implemented to be fixedly coupled. At this time, the temperature control member 1220 may transfer heat energy to the coolant flowing inside the pipe through one surface.

Meanwhile, a porous member 1240 may be disposed inside the pipe. The porous member 1240 disposed inside the pipe can transmit heat energy transferred from the temperature control member 1220 via the pipe to the coolant. Here, the porous member 1240 may have a porous structure including a plurality of pores, and the contact area with the coolant can be increased due to the porous structure, so heat energy is transmitted to the coolant passing through the plurality of pores. It can perform the delivery function more efficiently.

The insulation member 1260 may be disposed around one side and the other side of the tube of the coolant temperature control unit 1200.

Referring again to FIG. 7 , the first insulation member 1261 may be disposed and fixed between the nozzle unit 1300 and one side of the pipe located on the nozzle unit 1300 side. Through this, the first insulation member 1261 can thermally isolate external components, including the nozzle unit 1300, from the coolant temperature control unit 1200.

The second insulation member 1262 may be disposed and fixed between the coolant flow control unit 1100 and the other side of the tube located on the coolant flow control unit 1100 side. Through this, the second insulation member 1262 can thermally isolate external components, including the coolant flow control unit 1100, from the coolant temperature control unit 1200.

Here, the insulation member 1260 may be made of a material having a thermal conductivity of 10W/(m*K) or less. For example, the insulation member 1260 may be made of Teflon.

However, the location, thermal conductivity, and material of the above-mentioned insulating member are only examples, and the insulating member for thermally blocking external components from the coolant temperature control unit 1200 may be located at any appropriate location and any appropriate thermal conductivity. Of course, it can be provided as a material having .

FIG. 8 is a diagram showing a sensor module 1400 according to an embodiment of the present specification.

Referring to FIG. 8 , the sensor module 1400 may include a first temperature sensor 1410 and a second temperature sensor 1420.

The sensor module 1400 may be placed inside the body portion. For example, the sensor module 1400 may be placed and fixed outside the nozzle unit 1300. At this time, the sensor module 1400 and the nozzle unit 1300 may be disposed inside the body unit so that the center of the measurement area of the sensor module 1400 coincides with the center of the coolant injection area of the nozzle unit 1300. More specifically, the nozzle unit 1300 may include a guide unit 1310, and the guide unit 1310 may include a target limiting member 1312 that contacts the skin and defines a target area. At this time, the sensor module 1400 is set to the central axis (CA) of the body so 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. ) and may be fixed to the outer periphery of the nozzle unit 1300.

The sensor module 1400 may include at least one temperature sensor. In other words, the sensor module 1400 may include a first temperature sensor 1410 and a second temperature sensor 1420.

At this time, the first temperature sensor 1410 and the second temperature sensor 1420 may be disposed inside the body portion located in the same direction with respect to the nozzle portion 1300.

For example, referring again to FIG. 8 , the first temperature sensor 1410 and the second temperature sensor 1420 may be disposed in the lower area of the inner surface of the body with respect to the nozzle unit 1300. For example, the tip of the first temperature sensor 1410 may be disposed relatively closer to the front end (F) of the body than the tip of the second temperature sensor 1420. That is, the first temperature sensor 1410 may be placed closer to the front end of the body portion than the second temperature sensor 1420. Through this structure, the size of the body can be miniaturized while accurately measuring the temperature of the target area.

At least one of the first temperature sensor 1410 and the second temperature sensor 1420 may measure temperature information of the target.

For example, target temperature information may be obtained based on target temperatures measured from the first temperature sensor 1410 and the second temperature sensor 1420. For example, the temperature information of the target may be obtained by weighting the temperature information of the target measured from the first and second temperature sensors or by selecting one of the temperature information of the target measured from the first and second temperature sensors.

For another example, target temperature information may be obtained using one of the first temperature sensor 1410 and the second temperature sensor 1420. Specifically, as will be described later in FIG. 19, when it is determined that the first temperature sensor 1410 and the second temperature sensor 1420 are operating normally, either the first temperature sensor 1410 or the second temperature sensor 1420 Only one temperature sensor can be activated to obtain temperature information of the target.

In particular, when obtaining temperature information of the target using only the second temperature sensor 1420 disposed relatively spaced apart from the front end (F) of the body, a lens may be additionally provided at the tip of the second temperature sensor 1420. there is.

By using at least one of the first and second temperature sensors 1410 and 1420, the power required to operate the temperature sensor can be saved, and the lifespan of the sensor module 1400 can be increased.

Meanwhile, the first temperature sensor 1410 and the second temperature sensor 1420 may be disposed inside the body symmetrically with respect to the central axis CA of the body, as shown in FIG. 8(b). At this time, the first temperature sensor 1410 and the second temperature sensor 1420 are located at the center of the temperature measurement area of the first temperature sensor 1410 and the second temperature sensor 1420, as shown in FIG. 8(a) ( The sensor module 1400 has a predetermined angle with respect to the central axis CA of the body portion so that the center C2 of the target area defined by C1) and the target limiting member 1312 are substantially the same, and the nozzle portion 1300 Of course, it can be fixed around the outside of .

However, the above-described arrangement of the sensor module 1400 is only an example and the technical idea of the present specification is not limited thereto, and any appropriate method that can accurately measure the temperature of the target area and reduce the size of the cooling device 1000 is used. It can be implemented as a structure.

Meanwhile, although not shown in the drawings, the cooling device 1000 according to an embodiment of the present specification may further include a coolant pressure maintainer (Cryogen Pressure Keeper) that maintains the pressure of the coolant at a preset pressure. As an example, the coolant pressure maintenance unit may be provided within the cooling device 1000. For example, the coolant pressure maintaining part may be located in a gripping part that the user can grip. For another example, the coolant pressure maintaining unit may be located on the body.

The coolant pressure maintenance unit maintains the coolant at a high pressure, prevents pressure loss of the coolant, and allows the coolant to be sprayed at a fast response rate.

For example, the coolant pressure maintaining unit may cool the coolant. Specifically, the coolant pressure maintenance unit can cool the coolant using a Peltier element. Additionally, the coolant pressure maintenance unit cools the coolant before it flows into the coolant temperature control unit 1200, thereby maintaining the coolant flowing into the coolant temperature control unit 1200 at a high pressure. Additionally, the coolant pressure maintenance unit may be provided to further include a heat dissipation unit for dissipating heat generated from the Peltier element.

At this time, the coolant pressure maintenance unit can be applied to the cooling device 1000 using the cartridge-type coolant supply unit 4000 related to FIG. 2. However, the coolant pressure maintenance unit can be more advantageously applied to the cooling device 1000 using the coolant supply unit 4000 in the form of a coolant tank related to FIG. 3.

Hereinafter, with reference to FIGS. 9 to 18, the structure of the filter fixing module 2000 disclosed in this specification and the coupling relationship between the filter fixing module 2000 and the cooling device 1000 will be described in detail. The filter fixing module 2000 disclosed in this specification may be provided in a structure that can accommodate a filter therein while perforating the coolant supply unit 4000. In addition, the cooling device 1000 disclosed in the present specification is coupled to the coolant supply unit 4000 and includes a coupling member ( 1840).

The filter fixing module 2000 according to an embodiment disclosed in this specification may be formed in a structure in which the coolant supply unit 4000 is screwed to the thread formed on the coupling member 1840. Additionally, the filter fixing module 2000 may be formed in a structure that can accommodate a filter inside the filter fixing module 2000. Through this structure, the filter fixing module 2000 according to an embodiment disclosed in the present specification couples the coolant supply unit 4000 to the cooling device 1000, and cools the coolant discharged from the coolant supply unit 4000 through the filter. It may be provided in a structure that accommodates a filter to be introduced into the device 1000.

Meanwhile, the connection part 1800 of the cooling device 1000 may be provided in a structure having threads so as to be screwed together with the coolant supply part 4000. For example, the coupling member 1840 of the connection part 1800, which will be described later, may include a thread structure and may be provided for screw connection with the thread of the coolant supply unit 4000. Through this structure, the coolant discharged from the coolant supply unit 4000 is prevented from being exposed to the outside, thereby minimizing the risk of the coolant expanding.

FIG. 9 is a diagram showing the internal structure of a cooling device 1000 equipped with a filter fixing module 2000 according to an embodiment of the present specification.

Referring to FIG. 9, the filter fixing module 2000 is mounted on the connection part 1800 of the cooling device 1000, thereby supplying coolant to the inlet 1110 of the coolant flow control unit 1100.

More specifically, the filter fixing module 2000 may be mounted on the inner surface of the coupling member 1840 screwed to the thread on the inner surface of the housing 1820 of the connection part 1800. At this time, with the filter fixing module 2000 mounted on the inner surface of the coupling member 1840, 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. there is. For example, the front end (FE) of the coupling member 1840 is formed through screw coupling between the thread formed on the outer surface of the inlet 1110 of the coolant flow control unit 1100 and the third thread structure 1848 of the coupling member 1840, which will be described later. The inlet 1110 of the coolant flow control unit 1100 may be connected.

The filter fixing module 2000 may be provided with a structure that provides a flow path for coolant connected to the front end FE of the coupling member 1840. Accordingly, coolant may flow from the filter fixing module 2000 into the inlet 1110 of the coolant flow control unit 1100.

Figure 10 is an exploded view of a cooling device 1000 equipped with a filter fixing module 2000 according to an embodiment of the present specification. Referring to FIG. 10, a thread 1120 may be formed on the outside of the inlet 1110 of the coolant flow control unit 1100.

Additionally, the coupling member 1840 of the connection portion 1800 may be provided as a structure including a base 1841, a first thread structure 1842, and a second thread structure 1844. Additionally, the first thread structure 1842 may be provided as a structure including at least one groove 1846.

At this time, the first thread structure 1842 and/or at least one groove 1846 may have a structure capable of receiving or combining the filter fixing module 2000.

For example, the grip portion 2300 of the filter fixing module 2000 is received in at least one groove 1846 formed in the first thread structure 1842, so that the filter fixing module 2000 is detachable from the coupling member 1840. Can be installed. This will be described in detail later in FIGS. 12 to 18.

The second threaded structure 1844 may be formed outside the first threaded structure 1842. For example, the second thread structure 1844 may be formed on the outer surface of the coupling member 1840 on which the first thread structure 1844 is formed. Here, the second thread structure 1844 may be provided to be screwed to the housing 1820 of the connection portion 1800.

A thread 1822 having a thread and a thread corresponding to the second thread structure 1844 may be formed on the inner surface of the housing 1820. At this time, the second thread structure 1844 and the thread 1822 on the inner surface of the housing 1820 are screwed together, so that the coupling member 1840 and the housing 1820 can be coupled. For example, 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 (e.g., coupling member 1840, coolant flow control unit ( The inlet 1110 of 1100 or the filter fixing module 2000 is provided to be surrounded by the housing 1820, so that it can be protected from external shocks, etc.

Meanwhile, the housing 1820 may be provided to have a structure coupled to a coupling member formed on the outside of the body portion of the cooling device 1000. For example, a coupling member having a structure corresponding to the coupling member formed on the outside of the body of the main body may be formed on the outer surface of the housing 1820, and the coupling member of the housing 1820 may be formed on the outer surface of the body of the main body. By being inserted into, it can be fixedly coupled to the body portion of the main body of the housing 1820.

Meanwhile, in FIG. 10 , the housing 1820 is shown as a separate component from the main body of the cooling device 1000, and the housing 1820 is shown to be coupled to the main body of the cooling device 1000. However, this is only an example, and the housing 1820 is formed as a single structure with the main body of the cooling device 1000, and the thread is formed on the main body to be screwed with the second thread structure 1844 of the above-described coupling member 1840. Of course, it can be provided to be formed on the inside of.

Figure 11 is a perspective view of the coupling member 1840 on which the filter fixing module 2000 is mounted according to an embodiment of the present specification.

Referring to FIG. 11, the coupling member 1840 may be provided in a structure that further includes a third thread structure 1848.

The third thread structure 1848 may be formed on the opposite side of the first thread structure 1842 with respect to the base 1841 of the coupling member 1840. At this time, the third thread structure 1848 may be provided to have threads and threads corresponding to the thread 1120 formed on the outside of the inlet 1110 of the coolant flow control unit 1100 described above. Accordingly, the third thread structure 1848 and the thread 1120 of the inlet 1110 can be screwed together. Through this, the coupling member 1840 and the coolant flow control unit 1100 can be connected. In addition, the coolant movement passage 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 flow 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.

However, the above-described structure is only an example, and the coolant is transferred from the filter fixing module 2000 to the coolant flow control unit by using a coupling member of an appropriate form for mounting the filter fixing module 2000 to the cooling device 1000. Any suitable coupling structure may be provided to feed into the inlet 1110 of 1100.

Please refer to Figure 12. FIG. 12 is a diagram showing how the filter fixing module 2000 and the coupling member 1840 are coupled according to an embodiment of the present specification.

Referring to FIG. 12, the filter fixing module 2000 is accommodated or coupled to the coupling member 1840 by receiving grip members 2310 and 2320 in at least two grooves 1846 formed on the inner surface of the coupling member 1840, respectively. It can be. Meanwhile, although not shown in FIG. 12, the coolant supply unit 4000 may be screwed to the first thread structure 1842 of the coupling member 1840 while the filter fixing module 2000 is accommodated in the coupling member 1840. You can. Accordingly, the filter fixing module 2000 may be provided to be disposed between the cooling device 1000 and the coolant supply unit 4000 screwed to the coupling member 1840 of the cooling device 1000.

Here, for easy use by the user, the filter fixing module 2000 may include a grip portion 2300. For example, the grip unit 2300 may include at least two grip members 2310 and 2320. In other words, the grip unit 2300 may include a first grip member 2310 and a second grip member 2320. The user can easily mount or detach the filter fixing module 2000 from the cooling device 1000 by applying force to the first grip member 2310 and the second grip member 2320.

Meanwhile, the coupling member 1840 may have a first thread structure 1842 including at least one groove 1846 as described above. At this time, the first grip member 2310 and the second grip member 2320 may be fitted into at least one groove 1846 of the first thread structure 1842. For example, the first and second grip members 2310 and 2320 may be provided in a curved flat shape. At this time, each of the partial regions of the curved flat 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 thread structure 1842. Accordingly, the first grip member 2310 is fitted into the first groove 1846a of the first thread structure 1842, and the second grip member 2320 is fitted into the second groove 1846b of the first thread structure 1842. By fitting into the filter fixing module 2000, the filter fixing module 2000 can be detachably mounted on the coupling member 1840.

However, the structure and coupling relationship of the filter fixing member 2000 and the coupling member 1840 shown in FIG. 12 are only examples and are not limited thereto. For example, various numbers and shapes of grip members may be used to detachably mount the filter fixing member 2000 to the coupling member 1840. Alternatively, the filter fixing module 2000 may be mounted on the connection portion 1800 of the cooling device 1000 by including any suitable type of coupling member other than the grip member.

FIG. 13 is a diagram illustrating an aspect in which the coolant supply unit 4000 according to an embodiment of the present specification is screwed to the coupling member 1840 and perforated by the perforation member 2200 of the filter fixing module 2000.

Referring to FIG. 13, as described above in FIG. 12, the first grip member 2310 of the filter fixing module 2000 is connected to the first groove 1846a of the first thread structure 1842 of the coupling member 1840. is received, and the second grip member 2320 of the filter fixing module 2000 is received in the second groove 1846b of the first thread structure 1842 of the coupling member 1840, so that the filter fixing module 2000 is coupled. It may be mounted on member 1840.

At this time, the coolant supply unit 4000 may be perforated by the filter fixing module 2000 and may have a structure capable of being coupled to the coupling member 1840.

For example, the coolant supply unit 4000 may include a coolant discharge port perforated by the perforation member 2200 of the filter fixing module 2000. At this time, the diameter of the coolant discharge port may be larger than the outer diameter of the body of the perforating member 2200. Through this structure, the body of the perforating member 2200 can perforate the coolant discharge port of the coolant supply unit 4000.

Meanwhile, the outer surface of the body of the perforating member 2200 may be made of a material with high rigidity (eg, steel or stainless steel). On the other hand, the coolant discharge port of the coolant supply unit 4000 may be made of a material with low rigidity (eg, aluminum alloy or copper alloy). As another example, the outer surface of the body of the perforating member 2200 may have a relatively greater thickness than the coolant discharge port of the coolant supply unit 4000. Through this, the drilling member 2200 can easily drill a hole in the coolant supply unit 4000.

Additionally, the coolant supply unit 4000 may have a structure that can be coupled to the first thread structure 1842 of the coupling member 1840. For example, the coolant supply unit 4000 may have a thread structure including threads and threads corresponding to the first thread structure 1842. Accordingly, the coolant supply unit 4000 can be fixed to the coupling member 1840 through screw engagement with the first thread structure 1842 of the coupling member 1840.

Since the filter fixing module 2000 disclosed in the present specification can be provided with a structure that can accommodate the filter inside while drilling the coolant supply part 4000, the filter fixing module 2000 uses the coolant supply part 4000 as a coupling member. While being more easily coupled to (1840), it can provide the advantage that the coolant discharged from the coolant supply unit 4000 can be configured to pass through a filter.

Refer to Figures 14 to 16. Figure 14 is an exploded view of the filter fixing module 2000 according to an embodiment of the present specification. FIG. 15 is a diagram illustrating the body 2100 and the grip portion 2300 of the filter fixing module 2000 according to an embodiment of the present specification. FIG. 16 is a diagram illustrating the 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.

14 to 16, the filter fixing module 2000 according to one embodiment 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 to accommodate at least a portion of the filter and the sealing member 2400.

For example, 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 the side surfaces of the filter and the sealing member 2400. It may be provided as 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. For example, when the filter and the sealing member 2400 disposed in the filter fixing module 2000 have a flat disk shape, 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. For example, the receiving surface 2140 may be provided to extend along a first direction from the outer edge of the supporting surface 2120.

At this time, the receiving surface 2140 may be provided to have a shape corresponding to the shape of the filter and the sealing member accommodated in the receiving surface 2140.

For example, when the filter and the sealing member 2400 have a flat disk shape, the receiving surface 2140 may be provided to surround at least the side surface of the filter and the sealing member 2400, so the receiving surface 2140 is formed between the filter and the sealing member 2400. It may be provided to have a curved surface corresponding to the curved surface of the sealing member 2400.

In another example, the shape of the filter is polygonal or star-shaped, and the vertex has a size corresponding to the receiving surface 2140, so that the coolant is cooled by increasing the contact surface between the receiving surface 2140 and the sealing member 2400. Sealing can be improved.

Meanwhile, the body 2100 may further include a hole that can function as a passage for coolant to move. For example, referring to FIGS. 14 and 15 , the body 2100 is located at the center of the support surface 2120 and may be provided as a structure including a connection hole connected to the second end of the perforation member 2200. The connection hole of the body 2100 can accommodate the coolant output from the second end of the perforation member 2200 and function as a flow path for the coolant to output the coolant in the direction of the cooling device 1000. For example, 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 to the coolant flow control unit 1100 of the cooling device 1000. ) can be supplied to the inlet 1110. Through the structure of the filter fixing module 2000, the coolant from which impurities have been removed can flow into the cooling device 1000 and be sprayed on the target, thereby minimizing infection of the cooling device 1000 and the target due to impurities. there is.

The perforation member 2200 is connected to the support surface 2120 of the body 2100 and may be provided to perform the function of perforating the coolant supply unit 4000. For example, the perforating member 2200 has 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 direction from the first end to the second end. It may be provided as a structure including an elongated body. For example, the perforating member 2200 may be provided to extend along a second direction opposite to the first direction in which the receiving surface 2140 extends based on the support surface 2120 of the body 2200.

Meanwhile, the body of the perforating member 2200 includes a hollow hole formed therein to output the coolant discharged from the coolant supply unit 4000 to the inlet 1110 of the coolant flow control unit 1100 through the coupling member 1840. It can be provided in a structure that does.

The grip members 2310 and 2320 extend from the body 2100 and may be configured to be mounted on the connection portion 1800.

For example, the grip members 2310 and 2320 may be provided to extend from the support surface 2120 toward the outside of the support surface 2120 where 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 where 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 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 portion 1800, thereby forming a cooling device. In order to be mounted on 1000, it may be provided to have a size and shape corresponding to the size and shape of at least one groove 1846.

For another example, the first grip member 2310 and the second grip member 2320 may be provided in a bent flat shape. For example, referring again to FIG. 15, each of the first grip member 2310 and the second grip member 2320 has a first area P1 extending in the second direction and a direction having a predetermined angle with the second direction. It may be provided as a bent flat-shaped structure including a second area (P2) extending to .

Specifically, the first grip member 2310 has a bent plate shape including a first area (P1) extending in a second direction and a second area (P2) extending in a third direction having a predetermined angle with the second direction. It can be prepared with a structure of. Meanwhile, the second grip member 2320 has a bent plate shape including a first area (P1) extending in a second direction and a second area (P2) extending in a fourth direction having a predetermined angle with the second direction. It can be prepared with a structure of. At this time, the fourth direction may be different from the third direction. In addition, 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 angle formed by the first area P1 of the second grip member 2320. It may be substantially the same as the angle formed by the second area P2 of the second grip member 2320. 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 substantially parallel and spaced apart by a first distance. Additionally, 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 in which they are spaced apart by a second distance that is different from the first distance. . At this time, 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 larger than the first distance.

Meanwhile, 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 thread of the coupling member 1840 of the connection portion 1800, as described above. It can be mounted on the cooling device 1000. In addition, 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 thread of the coupling member 1840 of the connection portion 1800, as described above. It can be mounted on the cooling device 1000.

Through the structure of the first grip member 2310 and the second grip member 2320 described above, the first grip member 2310 and the second grip member 2320 can protrude to the outside of the cooling device 1000. It can be configured. Accordingly, the user can easily apply force to the first grip member 2310 and the second grip member 2320, resulting in the advantageous effect of being able to easily attach and detach the filter fixing module 2000 from the cooling device 1000. It can exist. This will be described in detail later in Figures 17 and 18.

Meanwhile, the filter fixing module 2000 may include at least one sealing member 2400. At least one sealing member 2400 may prevent leakage of the coolant and block the coolant from the outside.

For example, the filter fixing module 2000 may include a first sealing member 2410 accommodated in the support surface 2120 and the receiving surface 2140. Specifically, the first sealing member 2410 is provided in the shape of a flat disk, is disposed in a first direction with respect to the body 2100, and can be accommodated inside the filter fixing module 2000 by the receiving surface 2140. Additionally, the first sealing member 2410 may be made of a material such as Teflon.

The first sealing member 2410 may perform a function of preventing the coolant output through the first end of the perforating member 2200 from leaking to the outside. For example, the first sealing member 2410 may perform a function of reducing the outflow of coolant through the contact surface between the support surface 2120 and the first sealing member 2410. At this time, in order to increase airtightness 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. As a specific example, the shape of the filter may be changed to 1 It can be configured as a polygon or star shape with vertices corresponding to the outer circumference of the sealing member 2410.

Meanwhile, the first sealing member 2410 may be provided in a structure including a hole 2412 that functions as a passage for the coolant discharged through the first end of the perforating member 2200. For example, the first sealing member 2410 may be provided to have a structure including a hole 2412 at the center, and the hole 2412 of the first sealing member 2410 is located at the first end of the perforation member 2200. It may be formed in a structure capable of accommodating coolant that is output through or has passed through a filter, and outputting the received coolant in the direction of the cooling device 1000.

For another example, 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 located based on the support surface 2120 of the body 2100. can do. For example, the second sealing member 2420 is inserted into the body of the perforation member 2200, so that the direction in which the first sealing member 2410 is located relative to the support surface 2120 of the body 2100 (e.g., It may be disposed on the opposite side (e.g., second direction) of the first direction. Additionally, the second sealing member 2420 has a flat disk shape similar to the first sealing member 2410 and may be made of a material such as Teflon.

The second sealing member 2420 may function to reduce leakage of the coolant to be provided from the coolant supply unit 4000 to the hollow hole of the perforation member 2200 to the outer surface of the perforation member 2200. Specifically, the second sealing member 2420 reduces the leakage of coolant discharged from the coolant supply unit 4000 and flowing into the second end of the perforation member 2200 to the outside through the outer surface of the perforation member 2200. It can be provided to do so.

Meanwhile, the second sealing member 2420 may be provided in a structure including a through hole 2422 through which the body of the perforating member 2200 passes. For example, the second sealing member 2420 may be provided to have a structure including a through hole 2422 at the center, and the through hole 2422 of the second sealing member 2420 is formed by the body of the perforation member 2200. It can be provided in a size and shape to correspond to the diameter and shape of the body so that it can be fitted. For example, the inner diameter of the second sealing member 2420 defined by the through hole 2422 may be provided to be larger than the outer diameter of the body of the perforating member.

Meanwhile, the second sealing member 2420 may be configured together with the coolant supply unit 4000. In this case, the second sealing member 2420 passes through the coolant supply unit 4000 and an adhesive, or is connected to one end of the coolant supply unit 4000. It can be provided together with the coolant supply unit 4000 through mechanical coupling through a shape corresponding to the shape of.

Through this second sealing member 2420, coolant flows from the coolant supply unit 4000 to the second end of the perforation member 2200, thereby providing an advantageous effect in that leakage of coolant can be reduced.

Meanwhile, the filter may have a shape corresponding to the filter fixing module 2000 so that it is well fixed within the filter fixing module 2000. For example, the filter may be circular with a diameter corresponding to the inner diameter of the filter fixing module 2000 (eg, the inner diameter of the receiving surface 2140).

Alternatively, 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, the filter has a vertex inside the filter fixing module 2000, specifically, on the inner diameter of the receiving surface 2140. It can be a polygon with a corresponding size. Alternatively, the filter may be provided in a star shape whose apex corresponds to the inner diameter of the inside of the filter fixing module 2000, specifically the receiving surface 2140.

Additionally, the filter may be placed on any of the coolant flow paths within the filter fixing module 2000.

For example, the filter may be positioned between the support surface 2120 of the body 2100 and the first sealing member 2410. At this time, the filter may perform the function of filtering out impurities in the coolant contained in the coolant that has passed through the first end of the perforation member 2200 and the hole of the body 2100.

At this time, 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 polygon or star shape with a vertex meeting the outer circumference of the first sealing member 2410.

However, the arrangement of the filter described above is only an example, and the purpose of supplying the coolant to the cooling device 1000 by removing impurities is achieved by placing the filter at an appropriate position on the flow path of the coolant in the filter fixing module 2000. It could be. For example, a filter fixing module 2000 having an arbitrary structure may be provided so that the filter can be positioned between the support surface 2120 of the body 2100 and the second sealing member 2420. Of course, the structures of the components of the filter fixing module 2000 may vary depending on the placement position of the filter.

Additionally, although a filter is shown in FIG. 14, the filter should not be interpreted as being included in the components of the filter fixing module 2000 disclosed in this specification. Therefore, even if any filter produced or distributed separately from the filter fixing module 2000 disclosed in this specification is used, it should be interpreted as falling within the scope of rights of the filter fixing module 2000 disclosed in this specification.

Referring again to FIG. 14 , the receiving surface 2140 of the body 2100 may be provided to extend from the edge of the supporting surface 2120 to a first length L1 along a first direction. Meanwhile, the thickness of the first sealing member 2412 accommodated in the receiving surface 2140 may be set to a second length L2 along the first direction. At this time, the first length L1 and the second length L2 may be the same, but may be provided to have different lengths.

For example, the receiving surface 2140 and the first sealing member 2410 may be provided so that the second length L2 is larger than the first length L1. Through this structure, it can be easier to arrange the first sealing member 2410 to be received in the receiving surface 2140 or to separate the received first sealing member 2410 from the receiving surface 2140. However, this is only an example, and of course, the length of the receiving surface 2140 and the thickness of the first sealing member 2410 can be provided in various ways.

Meanwhile, as described above, the perforating member 2200 has 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 first end. It may include a body extending to two ends. At this time, the length in the longitudinal direction (eg, second direction) of the body may be provided as the third length L3. Additionally, the body of the perforating member 2200 may be provided to penetrate through the through hole 2422 of the second sealing member 2420. At this time, the thickness of the second sealing member 2420 may be set to a fourth length L4 along the second direction. At this time, the third length L3 and the fourth length L4 may be the same, but may be provided to have different lengths.

For example, the perforation member 2200 and the second sealing member 2420 may be provided so that the third length L3 is larger than the fourth length L4. Through this structure, the perforation member 2200 penetrates the through hole 2422 of the second sealing member 2420 and the protruding extra body area perforates the coolant supply part 4000, thereby forming a perforation from the coolant supply part 4000. While the coolant flows into the second end of the member 2200, the leakage of the coolant to be supplied from the coolant supply unit 4000 to the second end of the perforated member 2200 can be reduced by the second sealing member 2420. there is. However, this is only an example, and of course, the length of the perforation member 2200 and the thickness of the second sealing member 2420 can be provided in various ways.

Meanwhile, the first and second grip members 2310 and 2320 may be provided at a fifth length L5 along the second direction. At this time, the third length L3 and the fifth length L5, which are the lengths of the body of the perforating member 2200, may be the same, but may be provided to have different lengths.

For example, the perforation member 2200 and the first and second grip members 2310 and 2320 may be provided so that the fifth length L5 is larger than the third length L3. For another example, the first and second grip members 2310 and 2320 may be provided such 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. there is.

Through this structure, the first and second grip members 2310 and 2320 can protrude outward from the coolant supply portion 4000 perforated by the perforation member 2200. Therefore, 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.

Referring to FIG. 16, the first sealing member 2410 may be provided to have a size and shape that can be accommodated within the receiving surface 2140. For a specific example, the first sealing member 2410 may have a flat disk shape corresponding to the shape of the receiving surface 2140 and may be provided to have a diameter that can be accommodated in the receiving surface 2140.

For example, the first sealing member 2410 may be provided to have a diameter D1 smaller than the diameter D2 formed by the receiving surface 2140.

Through this, the first sealing member 2410 can be accommodated in the receiving surface 2140 and has the function of reducing the leakage of coolant flowing from the first end of the perforation member 2200 toward the cooling device 1000. It can be performed efficiently.

However, the shape and size of the first sealing member 2410 and the receiving surface 2140 shown in FIG. 16 are only examples, and any shape that can accommodate the first sealing member 2410 within the receiving surface 2140 The first sealing member 2410 and the receiving surface 2140 may be provided in appropriate shapes and sizes.

See Figure 17. FIG. 17 is a diagram 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.

Referring to FIG. 17, as described above, the coolant supply unit 4000 is perforated by the perforation member 2200 of the filter fixing module 2000 and screwed with the first thread structure 1842 of the coupling member 1840. , can be mounted on the cooling device 1000. At this time, while using the cooling device 1000 or when the use of the cooling device 1000 is completed, the user rotates the coolant supply unit 4000 to create the first thread structure ( 1842) The screw connection between the liver can be separated.

For example, 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 engage, thereby (4000) moves from the first direction to the second direction. Accordingly, the screw connection between the thread of the coolant supply unit 4000 and the thread of the first thread structure 1842 of the coupling member 1840 may be separated.

In addition, 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 engage, thereby (4000) moves from the first direction to the second direction. Accordingly, the coolant supply unit 4000 may be spaced apart from the perforating member 2200. In other words, the coolant supply unit 4000 may be separated from the filter fixing module 2000.

Meanwhile, when the use of the coolant supply unit 4000 is completed, coolant in a gaseous state may remain in the coolant supply unit 4000. At this time, if the remaining coolant is suddenly exposed to the atmosphere, the coolant may suddenly expand due to the difference between the internal pressure of the coolant supply unit 4000 and atmospheric pressure, which may cause noise and inconvenience to the user.

On the other hand, when the coolant supply unit 4000 disclosed in this specification is separated from the coupling member 1840, especially when the coolant supply unit 4000 begins to separate from the perforation member 2200 of the filter fixing module 2000, the coolant supply unit 4000 is separated from the coupling member 1840. A space that can function as a fluid passage may be formed in the inner area of the coupling member 1840 between the 4000 and the filter fixing module 2000. At this time, the gaseous coolant remaining in the coolant supply unit 4000 may be gradually discharged to the outside using the area between the coolant supply unit 4000 and the filter fixing module 2000 as a fluid passage. Therefore, according to the structure of the filter fixing module 2000 and the coolant supply unit 4000 disclosed in this specification, the pressure difference that may occur momentarily when the coolant supply unit 4000 is separated from the cooling device 1000 Noise and user inconvenience can be minimized.

In FIG. 17, only the state in which the coolant supply unit 4000 is separated is shown, but this is only for convenience of explanation. When the coolant supply unit 4000 is rotated clockwise (or counterclockwise), the coolant supply unit 4000 By engaging the threads of the first 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 thread of the coolant supply unit 4000 may be coupled to the coupling member 1840 through screw engagement with the first thread structure 1842, and the coolant supply unit 4000 may be perforated by the perforation member 2200.

See Figure 18. FIG. 18 is a diagram illustrating a state in which the filter fixing module 2000 is separated from the coupling member 1840 according to an embodiment of the present specification.

Referring to FIG. 18, as described above, in the filter fixing module 2000, the first grip member 2310 is inserted into the groove 1846a included in the thread 1842 of the coupling member 1840 and the second grip. The member 2320 may be mounted on the coupling member 1840 by being inserted into the groove 1846b included in the thread 1842 of the coupling member 1840. At this time, the user applies force F1 to the first and second grip members 2310 and 2320 protruding to the outside while using the cooling device 1000 or when the use of the cooling device 1000 is completed, thereby filtering the filter. The fixing module 2000 can be separated from the coupling member 1840.

Specifically, the user applies force F1 to the second area of the first and second grip members 2310 and 2320 that protrude to the outside, thereby causing the first and second grip members 2310 and 2320 to adhere to the coupling member 1840. It can be separated from the grooves 1846a and 1846b included in the thread 1842.

For example, 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.

For another example, the user applies force in a direction in which the first grip member 2310 and the second grip member 2320 approach, 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.

However, the direction of force applied to the first and second grip members 2310 and 2320 shown in this specification and drawings is only an example, and the first and second grip members 2310 and 2320 are connected to the coupling member 1840. A force may be applied in any suitable direction to dislodge the grooves 1846a and 1846b included in the thread 1842.

The filter fixing module 4000 according to an embodiment of the present specification may include a first grip member 2310 and a second grip member 2320 that protrude to the outside so that the user can easily apply force. Therefore, the filter fixing module 4000 according to an embodiment of the present specification can be easily separated from the coupling member 1840 with little force when use is completed.

In the above, referring to FIGS. 9 to 18, a filter fixing module including a body 2100, a perforation member 2200, a grip portion 2300, and/or a sealing member 2400 to be mounted on the coupling member 1840. (2000) was described focusing on the structure.

However, the structure of the components including the filter fixing module 2000, body 2100, perforation member 2200, grip portion 2300, and/or sealing member 2400 described in relation to FIGS. 9 to 18 is This is just an example. Therefore, the interpretation is limited to the structures of the components such as the filter fixing module 2000, body 2100, perforation member 2200, grip portion 2300, and/or sealing member 2400 shown in this specification and drawings. It doesn't work.

Meanwhile, although not shown in FIGS. 9 to 18, a cover accommodating the coolant supply unit 4000 may be provided on the outside of the coolant supply unit 4000. At this time, threads or coupling elements may be present on the outer surface of the cover of the coolant supply unit 4000. Additionally, threads or coupling elements corresponding to threads or coupling elements formed on the outer surface of the cover of the coolant supply unit 4000 may be formed on the outer surface of the housing 1820 of the connection unit 1800. Accordingly, the cover of the coolant supply unit 4000 can be coupled to the housing 1820 of the connection unit 1800 through screwing or the like, and through this, the cooling device 1000 can be operated while the coolant supply unit 4000 is accommodated inside the cover. Of course, it can be configured to be mounted on.

The cooling device 1000 according to an embodiment of the present specification may spray the introduced coolant to the target area according to the coolant flow control of the coolant flow control unit 1100. Additionally, the cooling device 1000 can control the temperature of the coolant through the coolant temperature control unit 1200 and spray the coolant to the target area. At this time, the cooling device 1000 may be implemented to measure the temperature of the target area in real time and adjust the temperature of the coolant based on the temperature of the target area. Additionally, the cooling device 1000 may obtain a user's input for setting cooling conditions or a user's input for instructing the start of a cooling operation through the input module 1500. Additionally, the cooling device 1000 may provide cooling information during cooling to the user through the output module 1600.

The above-described operations can be controlled through the control module 1700 of the cooling device 1000. For example, the control module 1700 obtains an input related to a cooling condition or an input to initiate a cooling operation from the input module 1500, and operates 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 can be controlled. Additionally, the control module 1700 may determine whether the sensor module 1400 is operating normally and control whether the sensor module 1400 is active.

Meanwhile, since the cooling device 1000 performs a cooling operation on a target area that is part of the body, the safety of the cooling device 1000 is essential. To this end, the cooling device 1000 according to an embodiment of the present specification may include at least two temperature sensors. At this time, the cooling device 1000 may be implemented using at least two temperature sensors to determine whether at least two or more temperature sensors are operating normally. Through this, the cooling device 1000 according to an 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 failure of the temperature sensor.

Hereinafter, with reference to FIGS. 19 to 28, various operations for controlling components of the cooling device 1000 of the control module 1800 according to an embodiment of the present specification will be described.

FIG. 19 is a flowchart related to the operation of the control module 1700 for determining whether the sensor module 1400 is operating normally according to an embodiment of the present specification.

The method of determining whether the sensor module 1400 shown in FIG. 19 is operating normally may be initiated when the cooling device 1000 is activated by the user's input to turn on the switch. Alternatively, the cooling device 1000 may be activated and may be initiated by additionally obtaining a user input that initiates an operation to determine whether the sensor module 1400 is operating normally. Alternatively, when the cooling device 1000 is activated, the control module 1700 may output information indicating the start of an operation to determine whether the sensor module 1400 is operating normally to the user through the output module 1600. there is. Here, the user can instruct the start of an operation to determine whether the sensor module 1400 is operating normally through the input module 1500, and the control module 1500 determines whether the sensor module 1400 is operating normally in response to the user input. It may be implemented to initiate an operation to determine whether it is operating.

Hereinafter, an embodiment of a method for determining whether the sensor module 1400 is operating normally, which is disclosed in this specification and performed by the control module 1700, will be described in detail.

Referring to FIG. 19, the method for determining whether the sensor module 1400 is operating normally includes activating the first temperature sensor and the second temperature sensor (S1100), the first temperature measured by the first temperature sensor, It may include 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). there is. In addition, a method for determining whether the sensor module 1400 is operating normally includes the step of deactivating at least one of the first temperature sensor and the second temperature sensor (S1400) or the first temperature sensor, depending on whether it falls within a preset threshold. It may be implemented to include a step of deactivating the temperature sensor and the second temperature sensor (S1500).

In the step of activating the first temperature sensor and the second temperature sensor (S1100), when the power of the cooling device 1000 is turned on and supply begins to be supplied to the control module 1700, the control module 1700 operates the sensor module ( 1400) may be implemented to activate.

For example, the sensor module 1400 may include at least two temperature sensors, as described above. At this time, 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.

When both the first temperature sensor 1410 and the second temperature sensor 1420 are activated, the sensor module 1400 controls a signal indicating that the first temperature sensor 1410 and the second temperature sensor 1420 are activated. It can be transmitted to module 1700.

See Figure 20. FIG. 20 is a diagram showing an aspect of measuring first temperature information and second temperature information to determine whether the sensor module 1400 is operating normally according to an embodiment of the present specification.

For example, when the first temperature sensor 1410 and the second temperature sensor 1420 are activated, the control module 1700 measures the temperature of the holder 3000 by using the guide unit 1310 through the output module 1600. Information indicating contact with the measurement area TD1 may be provided to the user.

When the guide unit 1310 is contacted by the user with the temperature measurement area (TD1) of the holder 3000, the first temperature sensor 1410 and the second temperature sensor 1420 each measure the temperature of the temperature measurement area (TD1). It can be measured. At this time, the sensor module 1400 obtains first temperature information T1 related to the temperature of the temperature measurement area TD1 of the holder 3000 obtained from the first temperature sensor 1410 and the second temperature sensor 1420. The second temperature information T2 related to the temperature of the temperature measurement area TD1 of the holder 3000 may be transmitted to the control module 1700.

In the step (S1200) of acquiring the first temperature information measured by the first temperature sensor and the second temperature information measured by the second temperature sensor, the control module 1700 determines the first temperature through the sensor module 1400. First temperature information T1 obtained from the sensor 1410 and second temperature information T2 obtained from the second temperature sensor 1420 may be obtained.

In the step of determining whether the difference between the first temperature information and the second temperature information is within a preset threshold (S1300), the control module 1700 uses the first temperature information T1 and the second temperature information acquired from the sensor module 1400. Based on the temperature information (T2), it is possible to determine whether the first temperature sensor 1410 and the second temperature sensor 1420 are operating normally, or the reliability of the first temperature information (T1) and the second temperature information (T2). there is.

For example, when the difference between the first temperature information (T1) and the second temperature information (T2) is large, the reliability of at least one of the first temperature information (T1) and the second temperature information (T2) is likely to be relatively low. This is high. On the other hand, when the difference between the first temperature information (T1) and the second temperature information (T2) is small, there is a high possibility that the first temperature information (T1) and the second temperature information (T2) have relatively good reliability.

Therefore, the control module 1700 determines the reliability of the first temperature information (T1) and the second temperature information (T2) based on the first temperature information (T1) and the second temperature information (T2) or the first temperature sensor (1410). ) and whether the second temperature sensor 1420 is operating normally can be determined.

For example, the 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. The reliability of T2) can be judged.

Additionally, the control module 1700 may be configured to calculate the difference between the first temperature information and the second temperature information based on the first temperature information (T1) and the second temperature information (T2).

Additionally, a threshold value may be set in advance in relation to the difference between the first temperature information and the second temperature information.

At this time, the control module 1700 can determine whether the difference between the first temperature information and the second temperature information falls within a preset threshold, and can control the subsequent operation of the cooling device 1000 accordingly. there is.

For example, if the difference value between the first temperature information and the second temperature information does not fall within a preset threshold, the reliability of at least one of the first temperature information (T1) and the second temperature information (T2) is relatively low. It may mean low. Here, relatively low reliability may mean that there is a high possibility that at least one of the first temperature sensor 1410 and the second temperature sensor 1420 will not operate normally. Alternatively, the first temperature sensor 1410 and the second temperature sensor 1420 operate normally, but one of the measured first temperature information (T1) and the second temperature information (T2) has an error due to external factors, etc. It may mean that something has occurred.

Therefore, if the difference value between the first temperature information and the second temperature information does not fall within a preset threshold, the control module 1700 operates the cooling device 1000 so as not to proceed with the subsequent cooling operation of the cooling device 1000. You can control it. Therefore, if the difference value between the first temperature information and the second temperature information does not fall within a preset threshold, the control module 1700 deactivates the first temperature sensor 1410 and the second temperature sensor 1420 (S1500) and may be configured to terminate the cooling operation.

On the other hand, if the difference value between the first temperature information and the second temperature information falls within a preset threshold, this may mean that the reliability of the first temperature information (T1) and the second temperature information (T2) may be relatively high. . In addition, there is a probability that at least one sensor among the first temperature sensor 1410 that acquired the first temperature information (T1) and the second temperature sensor 1420 that acquired the second temperature information (T1) is operating normally. It could mean high.

Accordingly, the control module 1700 may be configured to subsequently proceed with the cooling operation of the cooling device 1000 if the difference between the first temperature information and the second temperature information falls within a preset threshold.

For example, the control module 1700 may be configured to deactivate (S1400) at least one of the first temperature sensor 1410 and the second temperature sensor 1420. As described above, if the difference value between the first temperature information and the second temperature information falls within a preset threshold, the first temperature sensor 1410 and the second temperature information (T1) that acquired the first temperature information (T1) Since this may mean that there is a high probability that “at least one sensor” among the second temperature sensors 1420 that has acquired is operating normally, at least one of the first temperature sensor 1410 and the second temperature information (T1) By disabling the temperature sensor, the power required to measure the temperature of the temperature sensor can be saved.

Meanwhile, although not shown in FIG. 20, 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.

For example, in FIG. 20, while the guide unit 1310 is in contact with the temperature measurement area TD1 of the holder 3000, the user connects the first temperature sensor 1410 and the second temperature sensor through the input module 1500. (1420) temperature measurement can be indicated.

For example, the user may instruct temperature measurement of the first temperature sensor 1410 and the second temperature sensor 1420 through the second input module 1520 located on the grip part of the cooling device 1000. Here, the input indicating temperature measurement is a specific area (e.g., temperature measurement area TD1 of the holder 3000) for determining whether the first temperature sensor 1410 and the second temperature sensor 1420 are operating normally. It may be associated with an input directing the acquisition of temperature information.

The control module 1700 may control the sensor module 1400 so that the first temperature sensor 1410 and the second temperature sensor 1420 measure temperature in response to the user's input.

See Figure 21. FIG. 21 is a diagram showing how the control module 1700 calculates the difference between first temperature information and second temperature information to determine whether the sensor module 1400 is operating normally according to an embodiment of the present specification.

The control module 1700 provides first temperature information T1 and second information related to the temperature of the temperature measurement area TD1 of the holder 3000 obtained from the first temperature sensor 1410 through the sensor module 1400. Second temperature information T2 related to the temperature of the temperature measurement area TD1 of the holder 3000 obtained from the temperature sensor 1420 may be obtained.

For example, as described above, when the switch is turned on by the user, the first temperature sensor 1410 and the second temperature sensor 1420 may be activated. For example, a switch button may be formed at the bottom of the cooling device 1000 shown in FIG. 20. At this time, when the user turns on the switch button, the first temperature sensor 1410 and the second temperature sensor 1420 may be activated. At this time, the first temperature sensor 1410 and the second temperature sensor 1420 can measure the temperature of the temperature measurement area from the time 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 point from the time of activation.

For another example, as described above, the user may instruct measurement of the temperature of the temperature measurement area TD1 through the input module 1500. At this 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 area TD1 after the user's input is obtained. there is. For example, the control module 1700 determines the first temperature based on the first temperature information (T1) and the second temperature information (T2) at the time when the input indicating measurement of the user's temperature through the input module 1500 is obtained. It may be implemented to calculate the difference between the information (T1) and the second temperature information (T2).

Alternatively, the control module 1700 may provide first temperature information T1 and second temperature information at a time when a preset time has elapsed from the time an input indicating measurement of the user's temperature through the input module 1500 is obtained. It may be implemented to calculate the difference between the first temperature information (T1) and the second temperature information (T2) based on (T2).

However, the above is only an example, and various control methods allow the control module 1700 to acquire temperature information at an appropriate point in time or determine whether the sensor module 1400 is operating normally based on the temperature information. Of course, it can be implemented.

In addition, according to FIG. 21, when the user's input is obtained, the first temperature information (T1) and the second temperature information (T2) are shown to be obtained even before the time when the user's input is obtained, but this is only an example. Of course, the first temperature information (T1) and the second temperature information (T2) can be measured only when the user's input is obtained.

Meanwhile, although not shown in FIG. 19, 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, detects 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. For example, the control module 1700 may be configured to output to the user, through the output module 1600, information indicating that the first temperature sensor 1410 and the second temperature sensor 1420 are activated and instructing the user to perform a subsequent operation. You can.

For example, the control module 1700 may be configured to provide the user with information indicating contact of the guide unit 1310 to the temperature measurement area T1 of the holder 3000 through the output module 1600. .

For another example, the 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 that provides a notification sound. You can. For example, when the first temperature sensor 1410 and the second temperature sensor 1420 are activated, the control module 1700 detects the first temperature sensor 1410 and the second temperature sensor 1420 through the output module 1600. ) can be provided to the user.

At this time, as described above, the user will be able to instruct temperature measurement to determine whether the first temperature sensor 1410 and the second temperature sensor 1420 are operating normally through the second input module 1520. .

Meanwhile, although not shown in FIG. 19, if it is determined that it falls within the threshold in S1300, the control module 1700 sends information instructing the setting of cooling time information and/or cooling temperature information to the user through the output module 1600. It can be printed to .

For example, through the output module 1600 in the form of a display, information related to initiating the setting of cooling time information and/or cooling time information and/or cooling temperature information may be provided to the user in a visual form.

For another example, information related to initiating setting of cooling time information and/or cooling temperature information may be provided to the user in an audible form through the output module 1600 in the form of a speaker.

In response, the user can input cooling time information and/or cooling temperature information through the input module 1500. For example, 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 is described in detail in Figures 23 and 24.

However, the above is merely an example, and it goes without saying that any appropriate information may be provided to the user in a visual, auditory, and/or tactile form.

See Figure 22. FIG. 22 is a diagram showing an aspect of measuring 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.

For example, when measuring target temperature information after step S1400, the control module 1700 deactivates the second temperature sensor 1420 and measures the central temperature of the target more precisely by positioning it at a point closer to the target. To do this, temperature information on the target measured from the first temperature sensor 1410 can be obtained.

For another example, when measuring target temperature information after step S1400, the control module 1700 may deactivate the first temperature sensor 1410 and obtain temperature information of the target measured from the second temperature sensor 1420. You can. In this case, since the second temperature sensor 1420 is disposed relatively spaced apart from the target area than the first temperature sensor 1410, the second temperature sensor 1420 uses a lens 1430 to more accurately measure temperature information of the target. ) can be further provided.

However, this is only an example, and in relation to step S1400, the 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. Of course, it can be implemented to measure temperature.

Figure 23 is a flowchart related to the operation of the control module 1700 for obtaining an input for starting a cooling operation according to an embodiment of the present specification. Figure 24 is a diagram showing at least one input module 1500 according to an embodiment of the present specification. Figure 25 is a diagram showing an aspect of obtaining information related to cooling conditions through the first input module 1510 according to an embodiment of the present specification.

Cooling conditions related to cooling temperature, cooling time, etc. may vary depending on the type of treatment, treatment area, etc. Accordingly, the cooling device 1000 according to an embodiment of the present specification may be implemented so that the user can set cooling conditions related to cooling temperature, cooling time, etc. according to the desired treatment type.

Referring to Figure 23, the method of obtaining an input to initiate a cooling operation includes obtaining cooling temperature information and cooling time information (S2100) and obtaining a user's input to initiate a cooling operation (S2200). can do.

Referring to FIG. 24, as described above, the cooling device 1000 disclosed in this specification may include at least one input module.

For example, the cooling device 1000 includes one input module 1500, and the user inputs cooling time information and cooling temperature information or performs a cooling operation by varying the form of input using the single input module 1500. You can also order commencement. For example, the cooling device 1000 may be implemented to obtain different cooling time information and/or cooling temperature information by varying the time at which the user pushes a single input module 1500.

For another example, the cooling device 1000 may include a plurality of input modules 1500.

For example, the cooling device 1000 may include a first input module 1510 located adjacent to the distal end of the gripper. The first input module 1510 may be provided in various forms as described above. For example, the first input module 1510 may be configured in the form of a wheel switch, and the control module 1700 provides different information depending on the user's rotation and push of the wheel switch with respect to the first input module 1510. It can be configured to obtain.

For example, the cooling device 1000 may include a second input module 1520 located at a portion of the gripper where the user's fingers are positioned according to the user's grip. The second input module 1520 may be provided in various forms as described above. For example, the second input module 1520 may be provided in the form of a button, and the control module 1700 instructs the start of a cooling operation based on the user's input by pushing the second input module 1520. As described above, an input indicating measurement of the temperature of the temperature measurement area T1 can be obtained to determine the normal operation of the sensor module 1400.

By including a plurality of input modules 1500, the cooling device 1000 can provide an intuitive input form to the user and increase user convenience.

Referring again to FIG. 23, in the step of acquiring cooling temperature information and cooling time information (S2100), the control module 1700 determines cooling conditions including cooling temperature information and cooling time information through the first input module 1510. You can obtain information related to .

Referring to FIG. 25, the first input module 1510 may be provided in the form of a wheel switch, as described above.

Here, the user can input information related to cooling conditions by rotating or pushing the wheel switch.

For example, cooling temperature information may be obtained by rotating the first input module 1510 by the user. The user may set the target temperature for controlling the target to be high while rotating the first input module 1510 in the first direction. On the other hand, the user may rotate the first input module 1510 in the second direction and set the target temperature for controlling the target to be low. At this time, the output module 1600 may be configured to indicate to the user a change in cooling temperature information according to rotation of the wheel switch. Meanwhile, the user can complete the setting of cooling temperature information related to the target temperature to control the target by pushing the first input module 1510.

For another example, cooling time information may be obtained by rotating the first input module 1510 by the user. The user can set the cooling time to be long while rotating the first input module 1510 in the first direction. On the other hand, the user can set the cooling time to be short while rotating the first input module 1510 in the second direction. At this time, the output module 1600 may be configured to indicate to the user changes in cooling time information according to rotation of the wheel switch. Meanwhile, the user can complete setting the cooling temperature information related to the cooling time by pushing the first input module 1510.

However, the above is only an example, and information related to cooling conditions can be obtained through various input devices using various methods other than wheel switches. Additionally, information related to cooling conditions may be meant to encompass any appropriate information related to cooling operations other than cooling temperature information and cooling time information.

Referring again to FIG. 23 , in step S2200 of acquiring a user's input for starting a cooling operation, the control module 1700 may obtain a user's input for starting a cooling operation of the cooling device 1000.

For example, the control module 1700 may obtain a user input indicating the start of a cooling operation from the user through a second input module 1520 that is different from the first input module 1510. Specifically, the user can instruct the start of the cooling operation by pushing the second input module 1520 in the form of a button. However, this is only an example, and the user's input related to the start of the cooling operation can be obtained through various input devices using various methods other than buttons.

According to the above, when it is determined that the sensor module 1400 described in relation to FIG. 19 is operating normally, the cooling temperature information and cooling time information input mode may be initiated, and the input module (e.g., the first input The description focuses on 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.

However, this is only an example, and if the user does not input cooling temperature information and cooling time information through the first input module 1510, but inputs to start the cooling operation through the second input module 1520, Of course, the cooling device 1000 can be implemented to perform a cooling operation based on pre-stored cooling temperature information and cooling time information.

As described above, the 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 the user's input instructing the start of the cooling operation. can do. In addition, the control module 1700 may be configured to adjust the current applied to the coolant temperature controller 1200 based on information related to cooling conditions, including acquired cooling temperature information and cooling time information, and target temperature information. You can.

For example, the control module 1700 can control the opening and closing of the coolant flow control unit 1100 and the heat energy applied to the coolant by the coolant temperature control unit 1200, thereby controlling the amount of cooling delivered to the target area. there is.

For example, the control module 1700 can control the amount of cooling delivered to the target area by adjusting whether the coolant flow control unit 1100 is opened and closed and the opening and closing time.

For example, the control module 1700 controls whether to open and close the coolant flow control unit 1100 and the opening and closing time, and adjusts the heat energy applied to the coolant by the coolant temperature control unit 1200, thereby controlling the amount of cooling delivered to the target area. can be adjusted.

Hereinafter, with reference to FIG. 26, the method by which the control module 1700 controls the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 will be described in more detail.

Figure 26 is a flowchart showing how the control module 1700 controls the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 according to an embodiment of the present specification.

Referring to FIG. 26, the method by which the control module 1700 controls the coolant flow control unit 1100 and/or the coolant temperature control unit 1200 is as follows: ), a step of activating (S3100), a step of acquiring the measured temperature of the target through the sensor module 1400 (S3200), and the coolant temperature control unit 1200 is applied based on the set cooling temperature information and the measured temperature of the target. It may include controlling the current (S3300) and determining whether it falls within a set cooling time (S3400).

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 respect to FIG. 23. there is.

For example, the control module 1700 may activate the valve of the coolant flow control unit 1100 in response to a user's input to start cooling. Specifically, the control module 1700 may activate the valve of the coolant flow control unit 1100 to open it. Additionally, the control module 1700 may be configured to control the opening and closing time of the valve of the coolant flow control unit 1100 based on cooling time information set in relation to FIG. 23.

For example, the control module 1700 may activate the coolant temperature controller 1200 in response to a user's input to start cooling. For example, the 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. In addition, the control module 1700 controls the first temperature control member ( 1221) and/or the current value applied to the second temperature control member 1222 can be controlled.

Meanwhile, although not shown in FIG. 26, 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. For example, as described above with reference to FIG. 19 , at least one of the first temperature sensor 1410 and the second temperature sensor 1420 may be configured to be activated before step S3100. However, this is only an example, and even if the difference between the first temperature information (T1) and the second temperature information (T2) is within a preset threshold, the control module 1700 uses the first temperature sensor 1410 and the second temperature sensor After deactivating all of 1420, at least one of the first temperature sensor 1410 and the second temperature sensor 1420 may be activated in step S3100.

In the step of acquiring the measured temperature of the target through the sensor module 1400 (S3200), the control module 1700 may acquire the temperature of the target measured by the sensor module 1400. For example, 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. At this time, the sensor module 1400 may transmit the measured temperature of the target to the control module 1700.

In the step of controlling the current applied to the coolant temperature controller 1200 (S3300), the control module 1700 controls the preset cooling temperature information obtained in relation to FIG. 23 and the measured temperature of the target obtained in step S3200. Thus, it can be configured to control the current applied to the coolant temperature control unit 1200.

For example, when the preset cooling temperature information is lower than the measured temperature of the target, the control module 1700 applies the information to 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, the heat energy applied to the coolant from the first and second temperature control members 1221 and 1222 can be reduced, and the temperature of the coolant can be adjusted so that the temperature of the target approximates the preset cooling temperature.

For another example, when the preset cooling temperature information is higher than the measured temperature of the target, 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. ) can be adjusted to be high. Through this, the heat energy applied to the coolant from the first and second temperature control members 1221 and 1222 can be increased, and the temperature of the coolant can be adjusted so that the temperature of the target approximates the preset cooling temperature.

In the step of determining whether it is within the set cooling time (S3400), the control module 1700 determines whether the time at which the cooling operation was performed falls within the preset cooling time based on the preset cooling time information obtained in relation to FIG. 23. It can be configured. To this end, the control module 1700 may be configured to additionally obtain time information at the time the cooling operation started (eg, when the valve was opened, etc.) and current time information.

For example, if the time from the start of the cooling operation to the current time is less than the preset cooling time, the control module 1700 may determine that it falls within the preset cooling time.

At this time, the valve of the coolant flow control unit 1100 is continuously activated and can be controlled to spray the coolant to the target.

In addition, if it is determined that it is within the preset cooling time, the control module 1700 acquires 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. It may be configured to repeatedly perform the step of controlling the current applied to the coolant temperature controller 1200 (S3300) and the step of determining whether it falls within a set cooling time (S3400).

On the other hand, if the time from the start of the cooling operation to the current time exceeds the preset cooling time, the control module 1700 may be implemented to determine that it does not fall within the preset cooling time. At this time, the control module 1700 may be configured to end the cooling operation.

For example, if it is determined that the cooling time does not fall within the preset cooling time, the control module 1700 may be configured to deactivate the valve of the coolant flow control unit 1100. Additionally, if it is determined that the cooling time is not within the preset cooling time, the control module 1700 may be implemented to deactivate the coolant temperature controller 1200.

In other words, if it is determined that the cooling time is not within the preset time, the control module 1700 controls the components of the cooling device 1000 (e.g., coolant flow control unit 1100, coolant temperature control unit 1200, sensor module). (1400), etc.) may be configured to terminate the cooling operation.

See Figures 27 and 28. FIG. 27 is a flowchart showing how the control module 1700 disclosed in this specification outputs the measured temperature of the target through the output module 1600. FIG. 28 is a diagram showing how the temperature of a target measured through the output module 1600 disclosed in this specification is output.

Referring to FIG. 27, the control module 1700 can obtain the measured temperature of the target in real time from the sensor module 1400, and provide the measured temperature of the target to the user in real time through the output module 1600. .

The method of the control module 1700 outputting the measured temperature of the target includes acquiring 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 a set cooling time.

In the step (S3200) of acquiring the measured temperature of the target through the sensor module 1400, as described above, the control module 1700 uses at least one of the first temperature sensor 1410 and the second temperature sensor 1420. The temperature of the target measured from the temperature sensor can be obtained.

In the step of outputting the measured temperature of the target through the output module 1600 (S3210), the control module 1700 may transmit the measured temperature of the target obtained in step S3200 to the output module 1600.

Alternatively, the control module 1700 may transmit the cooling temperature information obtained in relation to FIG. 23 to the output module 1600.

Alternatively, the 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 performance time information to the output module 1600. Here, the cooling performance time information may be calculated based on the time information at the time the cooling operation was started and the current time information, as described above with reference to FIG. 26.

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 remaining cooling time information to the user based on the received remaining cooling time information.

For example, referring to FIG. 28 , the output module 1600 may output real-time temperature information of the target and the target temperature of the target to the user. Through this, the user can intuitively check whether the cooling operation is performed normally by comparing the real-time temperature of the target and the target temperature of the target to be controlled. Therefore, the cooling device 1000 according to an embodiment of the present specification can safely implement a skin cooling procedure while preventing side effects due to supercooling of the target, etc.

For another example, referring to FIG. 28, the output module 1600 may output remaining cooling time information to the user. Through this, the user can immediately modify and supplement the cooling procedure plan by comparing the remaining cooling time and the target procedure progress. Therefore, the cooling device 1000 according to an embodiment of the present specification can implement a cooling procedure that can increase the effect of the procedure while preventing side effects due to supercooling of the target, etc.

However, the content shown in FIG. 28 is only an example for convenience of explanation, and any appropriate information may be processed and provided to the user through the output module 1600.

Referring again to FIG. 27, similar to step S3400 of FIG. 26, the control module 1700 determines that the time at which the cooling operation was performed based on the preset cooling time information obtained in relation to FIG. 23 falls within the preset cooling time. It can be configured to determine whether

For example, if the time from the start of the cooling operation to the current time is less than the preset cooling time, the control module 1700 may determine that it falls within the preset cooling time.

At this time, the control module 1400 performs a step of acquiring the measured temperature of the target through the sensor module 1400 (S3200), a step of outputting the measured temperature of the target through the output module 1600 (S3210), and a set cooling time. It may be configured to repeatedly perform the step (S3220) of determining whether it falls within the range. That is, the control module 1400 may be configured to continuously obtain the measured temperature of the target and provide the measured temperature information of the target to the user in real time through the output module 1600.

On the other hand, if the time from the start of the cooling operation to the current time exceeds the preset cooling time, the control module 1700 may determine that it does not fall within the preset cooling time. At this time, the control module 1700 may be configured to end the cooling operation. For example, 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. In other words, the control module 1700 terminates the cooling operation by disabling the components of the cooling device 1000 (e.g., coolant flow control unit 1100, coolant temperature control unit 1200, sensor module 1400, etc.) It can be configured to do so.

In the above, various control operations of the control module 1700 have been described. However, this is only an example, and any appropriate method may be implemented to control the temperature of the target to the target temperature in order to minimize side effects of the cooling procedure and increase cooling efficiency while being safe.

10: cooling system 1000: cooling device
2000: Filter fixing module 3000: Holder
4000: Coolant supply unit

Claims (12)

In a cooling system that cools a target by spraying coolant,
a coolant storage that includes a coolant discharge port and discharges previously stored coolant by perforating the coolant discharge port;
A cooling device including an inlet through which the discharged coolant flows, and spraying the coolant introduced into the inlet to a target; and
It includes a structure interposed between the coolant reservoir and the cooling device based on the coupling of the coolant reservoir and the cooling device,
The structure is,
support surface;
A first sealing member interposed between one side of the support surface and the coolant discharge port based on the structure being coupled to the coolant reservoir, and including a through hole through which a perforating member that perforates the coolant discharge port penetrates; and
At least one grip member extending in one direction along the first axis from at least a portion of the outermost circumference of one side of the support surface,
Based on the structure being coupled to the coolant reservoir, an inner surface from the support surface constituting at least a portion of the at least one grip member to a first length is formed along an outer wall of the coolant reservoir,
Cooling system. According to claim 1,
The structure is,
Based on the fact that the structure is coupled to the coolant reservoir, the coolant discharge port is drilled through the through hole, and a first hollow hole (hollow) through which the coolant discharged through the perforated coolant discharge port can move Further comprising a perforating member including a hole),
Cooling system. According to clause 2,
The material constituting the perforation member has higher rigidity than the material constituting the coolant outlet,
Cooling system. According to clause 2,
The first hollow hole and the inlet are arranged in a row along an imaginary central axis perpendicular to the center of the support surface,
Cooling system. According to claim 1,
The structure is,
It further includes; a second sealing member interposed between the inlet and the other side of the support surface based on the structure being coupled to the cooling device,
Cooling system. According to claim 1,
The structure is,
A filter interposed between the other side of the support surface and the inlet based on the structure being coupled to the cooling device, and capable of removing at least a portion of impurities contained in the coolant discharged through the perforated coolant discharge port; containing,
Cooling system. According to claim 1,
The other side of the support surface has no protruding portion,
Cooling system. According to claim 1,
The coolant reservoir is a coolant cartridge,
Cooling system. In the structure interposed between the coolant reservoir and the cooling device based on the combination of the coolant reservoir and the cooling device,
support surface;
a first sealing member formed on one side of the support surface and including a through hole through which a perforating member that perforates the coolant discharge port passes; and
At least one grip member extending in one direction along the first axis from at least a portion of the outermost circumference of one side of the support surface,
The inner surface from the support surface to the first length constituting at least a portion of the at least one grip member is formed based on the outer wall of the coolant reservoir corresponding to the support surface to the first length,
struct. According to clause 9,
The structure is,
It further includes a perforation member that penetrates the through hole and includes a first hollow hole through which the coolant discharged through the perforated coolant discharge port can move.
struct. According to clause 9,
The structure is,
A filter disposed parallel to the other side of the support surface and capable of removing at least a portion of impurities contained in the coolant discharged from the coolant reservoir,
struct. According to clause 9,
The structure is,
It further includes a second sealing member disposed parallel to the other side of the support surface and capable of preventing the coolant released from the coolant reservoir from leaking to the outside.
struct.

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