KR102174725B1 - Hybrid cold device and magnetic stimulator having the same - Google Patents

Abstract

The present invention relates to a hybrid cooling device and a magnetic device comprising the same, comprising: a first cooling unit for lowering a temperature by first exchanging cooling water; And a second cooling unit for secondary heat exchange of the cooling water obtained by primary heat exchange through the first cooling unit, but precisely controlling a temperature, wherein the first cooling unit is composed of a cooling radiator unit, and the second cooling unit is It is characterized in that it provides a hybrid cooling device comprising a thermoelectric element type cooling heat exchange unit that precisely controls the temperature of the cooling water, and a magnetic device equipped with the same on a main body.
According to the present invention, it is possible to improve cooling efficiency, perform sophisticated temperature control, reduce vibration and noise compared to conventional cooling methods, and maintain a constant temperature of the cooling water through sophisticated temperature control. A device and a magnetic device device including the same can be provided.

Description

Hybrid cooling device and magnetic device including the same {HYBRID COLD DEVICE AND MAGNETIC STIMULATOR HAVING THE SAME}

The present invention relates to a hybrid cooling device and a magnetic device including the same, and more particularly, it is possible to perform sophisticated temperature control while improving cooling efficiency, and to reduce vibration and noise compared to conventional cooling methods. It is a hybrid cooling device capable of maintaining a constant temperature of cooling water through precise temperature control and a magnetic device device including the same.

In general, magnetic devices are devices that are used for the treatment of body parts by using a magnetic field, and induce a magnetic field by applying a pulse-type current to a coil. At this time, the magnetic field generated from the coil acts inside the body to generate a biocurrent. Is a treatment device using the principle of showing electrophysiological effects on each tissue of the human body.

The magnetic device includes a coil probe having a built-in coil for generating a magnetic field by a pulsed current applied from the main body, and a cooling device provided for cooling the coil.

At this time, the coil is mainly made by processing a material such as copper in the form of a thin and thin plate, and is made by winding it or by winding a wire. It is equipped.

The cooling device includes a water cooling method using water, an air cooling method in which heat is discharged using a heat sink, etc., and then cooled through a fan, and an oil cooling method in which oil is passed through the coil to cool the oil absorbed. Is being used.

However, the conventional water cooling method has higher cooling efficiency and easy maintenance compared to the air cooling method or oil cooling method, but it is impossible to directly contact the coil flowing with high voltage and high current, so after insulating the coil, cooling water flows from the outside. Since it is sent and cooled, cooling efficiency is low, there is a risk of damage or leakage of the outer case, and there is a problem that the insulation must be performed completely.

The conventional air cooling method has low cooling efficiency and is not suitable for high-power magnetic equipment, and the oil cooling method has a problem of lowering the cooling efficiency due to the high risk of oil leakage and the temperature rises slowly compared to water and cools slowly.

In addition, although a compressor or a radiator method is employed as a cooling device, they have a problem of large vibration and noise.

Incidentally, the conventional radiator method has a problem in that the fan rotates at high speed and wind passes through the radiator, causing vibration and noise, and precise temperature control is not possible, and the conventional compressor method also has high vibration and noise and is limited in precise temperature control. There was a problem with having.

Korean Patent Publication No. 10-0841596 Korean Patent Publication No. 10-1900491

The present invention solves the above-described conventional problems and was conceived in consideration thereof, and provides a hybrid cooling device capable of performing sophisticated temperature control on cooling water while improving cooling efficiency, and a magnetic device device including the same. There is a purpose.

An object of the present invention is to provide a hybrid cooling device capable of reducing vibration and noise compared to conventional cooling methods, and a magnetic device device including the same.

An object of the present invention is to provide a hybrid cooling device capable of maintaining a constant temperature of cooling water through sophisticated temperature control and a magnetic device device including the same.

The present invention uses a hybrid cooling device to reduce stress due to vibration and noise during the treatment of pain of a patient, and to improve overall stability of a magnetic device, and to enable continuous use, and a hybrid cooling device including the same. Its purpose is to provide magnetic equipment.

A hybrid cooling apparatus according to the present invention for achieving the above object includes: a first cooling unit for lowering a temperature by first heat exchange of cooling water; A second cooling unit configured to perform secondary heat exchange of the cooling water obtained by primary heat exchange through the first cooling unit but precisely control a temperature, wherein the first cooling unit is configured as a cooling radiator unit; The second cooling unit may be configured as a thermoelectric element type cooling heat exchange unit that precisely controls the temperature of the cooling water through a thermoelectric element.

Here, the cooling heat exchange unit includes: a heat exchange block for introducing and secondly cooling and heat exchange of cooling water obtained by heat exchange through the first cooling unit to discharge; A thermoelectric device module installed on the heat exchange block, for exquisitely controlling the temperature of the cooling water and for secondary heat exchange by using a temperature difference due to a Peltier effect; It may be configured to include a heat dissipating means for increasing heat exchange efficiency by being connected to the thermoelectric element module.

Here, the heat dissipation means comprises: a heat dissipation plate for absorbing heat by contacting the thermoelectric device module; It may be configured to include a heat radiation fan for quickly discharging the heat absorbed by the heat sink to the outside.

Here, by forming a thermal grease layer by applying thermal grease between the thermoelectric device module and the heat sink, it may be configured to increase heat transfer efficiency.

Here, the cooling heat exchange unit may control the temperature of the cooling water in an error range of ±0.1°C through the thermoelectric device module.

Here, a cooling water storage container for storing cooling water subjected to secondary heat exchange through the cooling heat exchange unit of the second cooling unit; It may include; a circulation pump for circulating the cooling water stored in the cooling water storage tank.

In addition, the magnetic device device according to the present invention for achieving the above object comprises: a main body provided to be movable; A coil probe connected to the main body and having a built-in coil for generating a magnetic field by an applied pulsed current; A cooling device installed inside the main body and used for cooling the coil, wherein the cooling device comprises: a first cooling unit configured to lower a temperature by first exchanging the cooling water heated by passing through the coil probe; And a second cooling unit for secondary heat exchange of the cooling water obtained by primary heat exchange through the first cooling unit, and used to remove heat from the coil probe side by precisely controlling and cooling the temperature, wherein the first cooling unit is a cooling radiator unit. And, the second cooling unit is characterized in that the hybrid cooling device configured as a thermoelectric element type cooling heat exchange unit that precisely controls the temperature of the cooling water through the thermoelectric element.

Here, the cooling heat exchange unit includes: a heat exchange block for introducing and secondly cooling and heat exchange of cooling water obtained by heat exchange through the first cooling unit to discharge; A thermoelectric device module installed on the heat exchange block, for exquisitely controlling the temperature of the cooling water and for secondary heat exchange by using a temperature difference due to a Peltier effect; It may be configured to include a heat dissipating means for increasing heat exchange efficiency by being connected to the thermoelectric element module.

Here, the heat dissipation means comprises: a heat dissipation plate for absorbing heat by contacting the thermoelectric device module; It may be configured to include a heat radiation fan for quickly discharging the heat absorbed by the heat sink to the outside.

Here, by forming a thermal grease layer by applying thermal grease between the thermoelectric device module and the heat sink, it may be configured to increase heat transfer efficiency.

Here, the cooling heat exchange unit may control the temperature of the cooling water in an error range of ±0.1°C through the thermoelectric device module.

Here, a cooling water storage container for storing cooling water subjected to secondary heat exchange through the cooling heat exchange unit of the second cooling unit; It may include; a circulation pump for circulating the cooling water stored in the cooling water storage tank.

According to the present invention, not only can the cooling efficiency be improved, but also precise temperature control of the cooling water can be performed, vibration and noise can be reduced compared to conventional cooling methods, and the temperature of the cooling water can be reduced through sophisticated temperature control. It is possible to provide a hybrid cooling device that can keep constant and a magnetic device device including the same.

The present invention removes and cools the heat generated from the coil probe side by using the flow of cooling water, and eliminates the risk of leakage due to external shock, and can significantly reduce discharge and electric shock accidents due to leakage. Compared to the cooling method, it is not only easier to control the outflow of refrigerant, but also the configuration of the cooling device can be simplified. Since the cooling water flows inside the coil, there are no structural and mechanical obstructions on the outside of the coil probe. It is possible to design an exterior housing of approximately the same size, which can provide a useful effect of positioning the precise focus range of the magnetic field.

The present invention can reduce the vibration and noise of the magnetic device by using the hybrid cooling device, so that stress due to vibration and noise can be reduced during the patient's pain treatment, and continuous use while increasing the overall stability of the magnetic device device. The usefulness of making it possible can be achieved.

1 is a block diagram showing a magnetic apparatus including a hybrid cooling device according to an embodiment of the present invention.
FIG. 2 is an external exemplary view showing a magnetic device including a hybrid cooling device according to an embodiment of the present invention.
3 is a schematic configuration diagram showing a hybrid cooling device provided in a main body of a magnetic device according to an embodiment of the present invention.

As for terms used in the present invention, general terms that are currently widely used are selected, but in certain cases, some terms are arbitrarily selected by the applicant. In this case, the meanings described or used in the specific contents for carrying out the invention are not just the names of terms. The meaning should be grasped in consideration of.

Hereinafter, the technical configuration of the present invention will be described in detail with reference to exemplary embodiments illustrated in the accompanying drawings.

1 is a configuration diagram showing a magnetic equipment device including a hybrid cooling device according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating a preferred embodiment of the present invention. It is an exemplary external view showing a magnetic device, and FIG. 3 is a schematic configuration diagram showing a hybrid cooling device provided in the main body of the magnetic device according to an embodiment of the present invention.

The hybrid cooling device 100 and the magnetic device 200 including the same according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3.

Hybrid cooling apparatus 100 according to an embodiment of the present invention, as shown in Figure 1, the first cooling unit 110, the second cooling unit 120, the cooling water storage tank 130, and the circulation pump 140. It consists of a configuration that includes.

The first cooling unit 110 is a configuration for lowering the temperature by primary heat exchange of cooling water, and may be configured as a small cooling radiator unit having a cooling function.

In this case, the first cooling unit 110 serves to lower the temperature by primarily heat-exchanging the high-temperature cooling water.

The second cooling unit 120 is a configuration for secondary heat exchange of cooling water obtained by primary heat exchange through the first cooling unit 110 constituted by the cooling radiator unit, but precisely controlling the temperature, and cooling water through a thermoelectric element It can be configured as a thermoelectric element type cooling heat exchange unit that precisely controls and cools the temperature of.

The thermoelectric element type cooling heat exchange unit is installed on the heat exchange block 121 and a heat exchange block 121 for introducing and secondly cooling and discharging the cooling water obtained through the first heat exchange through the first cooling unit 110. And a thermoelectric element module 122 for exquisitely controlling the temperature of the cooling water and for secondary heat exchange by using a temperature difference due to the Peltier effect, and a heat dissipation means connected to the thermoelectric element module 122 to increase heat exchange efficiency. I can have a composition that I do.

At this time, through the thermoelectric device module 122, the temperature of the cooling water may be precisely controlled within an error range of ±0.1°C.

Here, the heat dissipation means is a heat sink 123 for contacting the thermoelectric device module 122 and absorbing heat generated therefrom, and a heat dissipating fan for rapidly discharging heat absorbed by the heat sink 123 to the outside. It can be provided with (124).

Here, it may be configured to increase heat transfer efficiency and heat exchange efficiency by forming a thermal grease layer by applying thermal grease between the thermoelectric device module 122 and the heat sink 123.

The cooling water storage container 130 is configured to store cooling water obtained by secondary heat exchange through the thermoelectric element type cooling heat exchange unit of the second cooling unit 120.

The circulation pump 140 is a configuration for continuously circulating the cooling water stored in the cooling water storage container 130, and cooling the cooling water by sequentially passing through the first cooling unit 110 and the second cooling unit 120 Let it be processed.

Through the hybrid cooling device 100 according to the present invention having the above-described configuration, the first cooling unit 110 by the cooling radiator unit applied in a compact structure and the second cooling unit 120 by the thermoelectric element type heat exchange unit. ), compared to conventional cooling methods, can provide the advantage of performing sophisticated temperature control on the cooling water, thereby improving cooling efficiency, reducing vibration and noise, and enabling sophisticated temperature control. It is possible to provide the advantage of maintaining a constant temperature of the cooling water.

On the other hand, the magnetic apparatus 200 according to the present invention including the hybrid cooling device 100 having the above-described configuration will be described with reference to FIGS. 1 to 3 as follows.

The magnetic device 200 according to the embodiment of the present invention includes a main body 210, a coil probe 220, and a cooling device 100, as shown in FIGS. 1 to 3.

The main body 210 is provided as a body having an installation space for installing the cooling device 100 therein, but may be configured in various shapes.

In this case, the main body 210 is preferably provided to be movable by mounting a wheel such as a caster having a locking device.

The main body 210 is provided with an input unit for manipulating and setting the magnetic device 200 and a control unit for controlling the equipment as a whole based on a signal from the input unit.

The coil probe 220 is connected to the main body and has a built-in coil for generating a magnetic field by a pulsed current applied from DC power mounted on the main body 210.

At this time, the coil is provided in a tubular shape to facilitate cooling treatment by flowing cooling water, and to remove heat from the coil probe 220 side.

Here, the coil is constructed using a single continuous copper tube to eliminate or minimize the connection part on the path to prevent damage and leakage of the coil due to external shock.

The coil probe 220 may be configured as a plate-shaped body, and may be formed in various shapes.

The cooling device 100 is installed inside the body 210 to circulate and supply cooling water for use in cooling the coil, and the cooling water heated by passing through the coil probe 220 is first heat-exchanged. The first cooling unit 110 for lowering the temperature and the cooling water obtained by primary heat exchange through the first cooling unit 110 are secondarily heat-exchanged to cool, but the temperature is precisely controlled to remove heat from the coil probe 220 It can have a hybrid configuration including a second cooling unit 120 for use.

As described above, the cooling device 100 is preferably configured as a hybrid cooling device including the first cooling unit 110 and the second cooling unit 120 as described above.

That is, the first cooling unit 110 is a configuration for lowering the temperature by first heat exchange of cooling water, and may be configured as a small cooling radiator unit having a cooling function.

In this case, the first cooling unit 110 serves to lower the temperature by primarily heat-exchanging the high-temperature cooling water.

The second cooling unit 120 performs secondary heat exchange of the cooling water obtained by primary heat exchange through the first cooling unit 110 configured as the cooling radiator unit, but precisely controls the temperature to send it to the coil probe 220 to the coil side. As a configuration used to remove heat due to the generation of a magnetic field, it may be configured as a thermoelectric element type cooling heat exchange unit that precisely controls and cools the temperature of the cooling water through a thermoelectric element.

The thermoelectric element type cooling heat exchange unit is installed on the heat exchange block 121 and a heat exchange block 121 for introducing and secondly cooling and discharging the cooling water obtained through the first heat exchange through the first cooling unit 110. And a thermoelectric element module 122 for exquisitely controlling the temperature of the cooling water and for secondary heat exchange by using a temperature difference due to the Peltier effect, and a heat dissipation means connected to the thermoelectric element module 122 to increase heat exchange efficiency. I can have a composition that I do.

At this time, through the thermoelectric device module 122, the temperature of the cooling water may be precisely controlled within an error range of ±0.1°C.

Here, the heat dissipation means is a heat sink 123 for contacting the thermoelectric device module 122 and absorbing heat generated therefrom, and a heat dissipating fan for rapidly discharging heat absorbed by the heat sink 123 to the outside. It can be provided with (124).

Here, it may be configured to increase heat transfer efficiency and heat exchange efficiency by forming a thermal grease layer by applying thermal grease between the thermoelectric device module 122 and the heat sink 123.

In addition, the cooling device 100 includes a cooling water storage container 130 for storing cooling water secondary heat exchange through the thermoelectric element type cooling heat exchange unit of the second cooling unit 120, and stored in the cooling water storage container 130. As a configuration for continuously circulating cooling water, the cooling water is sequentially passed through the coil probe 220, the first cooling unit 110, and the second cooling unit 120 to remove heat from the coil probe 220 side. It includes a circulation pump 140 to be cooled.

Through the magnetic apparatus 200 according to the present invention having the above-described configuration, the first cooling unit 110 by the cooling radiator unit applied in a compact structure and the second cooling unit 120 by the thermoelectric element type heat exchange unit Through the configuration of the hybrid cooling device 100 including a, it is possible to provide an advantage of performing sophisticated temperature control on the cooling water compared to the conventional cooling methods, thereby improving cooling efficiency and reducing vibration and noise. In addition, since sophisticated temperature control is possible, not only can it provide the advantage of maintaining a constant temperature of the cooling water, but also can directly and effectively remove heat generated from the coil probe 220 side with a built-in coil by flowing the cooling water into the tube. Therefore, it is possible to increase the overall stability of the magnetic device device 200 and provide an advantage of enabling continuous use.

In addition, through the present invention, while removing heat generated from the coil probe 220 side by the flow of cooling water, and eliminating the risk of leakage due to external shock, it is possible to significantly reduce discharge and electric shock accidents due to leakage, Compared to the conventional oil cooling method, it is not only easier to control the outflow of refrigerant, but also the configuration of the cooling device can be simplified, and since the cooling water flows inside the coil, there are no structural and mechanical obstacles outside the coil probe 220 side. It is possible to design an external housing having the same size as the shape of the internal coil, thereby providing an advantage of enabling the position of the magnetic field field to be accurately calculated.

In particular, in the present invention, as the hybrid cooling device 100 reduces vibration and noise for the magnetic device 200, it is applied to a patient to reduce stress due to vibration and noise during pain treatment. Can provide.

The above description is an illustrative description of the present invention, and the embodiments published in the specification are not intended to limit the technical idea of the present invention, but to describe the present invention. Various modifications and variations will be possible without departing from the technical idea of Therefore, the scope of protection of the present invention is interpreted by the matters described in the claims, and technical matters within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: hybrid cooling device 110: first cooling unit
120: second cooling unit 121: heat exchange block
122: thermoelectric module 123: heat sink
124: radiating fan 200: magnetic device
210: main body 220: coil probe

Claims (12)

A main body provided to be movable;
A coil probe connected to the main body and having a built-in coil for generating a magnetic field by an applied pulsed current;
A cooling device installed inside the body and used for cooling the coil; Including,
The cooling device,
A first cooling unit for lowering a temperature by first exchanging the cooling water heated by passing through the coil probe; A second cooling unit used to remove heat from the coil probe side by performing secondary heat exchange of the cooling water, which has been subjected to primary heat exchange through the first cooling unit, but precisely controlling and cooling the temperature,
The first cooling unit is composed of a cooling radiator unit, the second cooling unit is a thermoelectric element type cooling heat exchange unit that precisely controls the temperature of the cooling water through a thermoelectric element,
The cooling heat exchange unit includes: a heat exchange block for introducing and secondly cooling and heat-exchanging cooling water through the first cooling unit to discharge; A thermoelectric device module installed on the heat exchange block and for exquisitely controlling the temperature of the cooling water and for secondary heat exchange by using a temperature difference due to a Peltier effect; And heat dissipation means connected to the thermoelectric device module to increase heat exchange efficiency. Including,
The radiating means may include a radiating plate for absorbing heat by contacting the thermoelectric device module; And a heat radiation fan for rapidly discharging heat absorbed by the heat sink to the outside. Consists of,
The thermal grease is applied between the thermoelectric device module and the heat sink to form a thermal grease layer, thereby improving heat transfer efficiency,
The cooling heat exchange unit controls the temperature of the cooling water in an error range of ±0.1°C through the thermoelectric device module,
A cooling water storage container for storing cooling water subjected to secondary heat exchange through the cooling heat exchange unit of the second cooling unit; And a circulation pump for circulating the cooling water stored in the cooling water storage tank. Magnetic device device comprising a. delete delete delete delete delete delete delete delete delete delete delete

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