KR100886951B1 - Cooling apparatus having thermoelectric module - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling device having a thermoelectric element, and more particularly, to a cooling device for cooling a circulating coolant to absorb heat generated from an electronic device or a mechanical device.

The cooling apparatus of the present invention is a cooling apparatus for cooling a cooling liquid circulating inside the apparatus to absorb heat generated in the apparatus, comprising: a pump for maintaining the flow of the cooling liquid in a constant direction; A cooling device connected to the coolant discharge port of the device and including a housing configured to constitute a plurality of moving passages of the coolant, and a thermoelectric element attached to the housing to cool the coolant; And a coolant storage tank configured to store the coolant, wherein the coolant movement passage is connected to a coolant outlet and is formed as a single pipe, and has an inlet portion having at least one coolant branch point and connected to the coolant branch point and a plurality of branch points. There is a technical feature that consists of a branch portion formed of a plurality of pipes including an integrated portion connected to the branch portion and formed of a single tube including a.

Chiller, Thermoelectric element, Pump, Coolant

Description

Cooling apparatus having thermoelectric module

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling device having a thermoelectric element, and more particularly, to a cooling device for cooling a circulating coolant to absorb heat generated from an electronic device or a mechanical device.

In general, a magnetic field therapy device using a magnetic field is a device that generates a magnetic field by applying a pulse current to the coil, and the current generated by the generated magnetic field is induced in the human tissue to stimulate and treat the affected part. Such a magnetic field therapy device has a coil for generating a magnetic field, and generates a magnetic field of a desired intensity around the coil by flowing a current of about thousands of ampere to the coil in a short time (50 to 300 mA).

1 is a diagram illustrating a circuit 100 of a conventional magnetic field therapy device.

는 스위칭 소자에 의해 펄스전류(I)가 자기장 유도 코일

에 흐른다. 이때, 자기장의 세기를 높이기 위해서는 전원측의 캐패시턴스(C)나 전압(V)을 높이면 된다.Referring to FIG. 1, energy charged in a large capacity capacitor connected to a power supply side is shown.

Is the magnetic field induction coil

Flows on. At this time, in order to increase the strength of the magnetic field, the capacitance C or the voltage V on the power supply side may be increased.

에 의해 코일에서 열로 소모된다.Therefore, by increasing the capacitance (C) or voltage (V), when a large current (I) flows in the coil, not only the magnetic field is induced from the energy (W _L ) but also some energy of W _L is Joule's law.

Is consumed as heat in the coil.

In addition, the heat generated continuously increases not only the inductance L of the coil, but also the internal resistance R of the coil, and as a result, more heat is generated in the coil by the Joule law.

Therefore, if the heat is not cooled effectively, the coil is overheated and the inductance value is changed, as well as the coil case surrounding the coil is overheated. These problems are not only dangerous to the patient, but also cause malfunction of the magnetic field therapy device, and thus cannot continuously carry out magnetic therapy.

In order to solve this problem, Patent No. 2007-54860, filed by the present applicant, consists of a copper tube and uses a condenser and a compressor to cool the cooling liquid.

Figure 2 is a block diagram showing a cooling apparatus of a conventional magnetic field treatment device.

2, the cooling device of the magnetic field treatment device is a coil 200, a pump 210, a coolant storage tank 220, a condenser 230, a temperature sensor 240, a control unit 250 and a compressor 260, etc. It consists of.

The coil 200 has a characteristic of generating a magnetic field by receiving a current, and may treat a patient using the magnetic field generated by the coil 200. In addition, the coil 200 generates heat together with the magnetic field. Therefore, the coil 200 is preferably manufactured in the form of a tube capable of circulating the coolant therein.

In addition, the coil 200 is made of a copper tube having high corrosion resistance, good thermal or electrical conductivity, and excellent mechanical properties, and the shape of the coil 200 is most preferably made of a pancake type that draws a circle from the inside.

In addition, the coil 200 made of a copper tube may be applied to any shape that can efficiently generate a magnetic field even if it is not a pancake type.

The pump 210 extracts the coolant from the coolant storage tank 220 to inject and circulate the inside of the coil 200.

The coolant storage tank 220 stores a low temperature liquid coolant. In addition, the coolant storage tank 220 also stores the coolant in a liquid state circulated inside the coil 200.

The coolant uses a commercially available refrigerant oil such as silicon oil or transformer oil to prevent corrosion of the coil 200.

The condenser 230 is interlocked with the coolant storage tank 220 and maintains the coolant in a low temperature state by air cooling.

The temperature sensor 240 is installed in the moving passage of the coolant circulated from the magnetic field generating coil 200 between the coolant storage tank 220 and the condenser 230 and measures the temperature of the coolant.

The controller 250 extracts the temperature of the coolant measured by the temperature sensor 240, and operates the fan of the condenser 230 when the temperature of the initially set coolant exceeds. In general, when the temperature of the coolant exceeds 43 degrees, the impedance increases, causing an abnormality in the device, and the generation efficiency of the magnetic field is reduced. Therefore, it is most preferable that the coolant set temperature of the control part 250 is 43 degrees or less.

In addition, the controller 250 may extract the temperature of a temperature sensor (not shown) installed outside the coil 200, and determine whether the pump is operated by comparing the temperature of the temperature sensor 240 of the coolant movement passage.

The compressor 260 is operated by the controller 250 when the temperature of the coolant in the temperature sensor 240 exceeds the set temperature. The compressor 260 is interlocked with the condenser 230 and maintains the temperature of the coolant at a low temperature by using the refrigerant gas. In consideration of environmental pollution, the refrigerant gas may be HFC (Hydro-Fluoro-Carbon), HCFC (Hydro-Chloro-Fluoro-Carbon), PFC (Per-Fluoro-Carbon), or the like.

In the conventional cooling apparatus illustrated in FIG. 2, the coil 200 is made of a copper tube to circulate a cooling liquid in the coil 200 to absorb heat generated from the coil 200, but the condenser is used to cool the cooling liquid. Since components such as the 230 and the compressor 260 must be provided, there is a disadvantage in that the structure is complicated and the volume is increased.

3 is a perspective view of a water-cooled cooling apparatus by cooling a heat generating portion of a conventional thermoelectric element 300.

Looking at the structure of the conventional water-cooled cooling apparatus with reference to Figure 3, a cooler (not shown) is formed on the cooling unit 310 side of the thermoelectric element 300, the water supply unit 350 and the heat generating unit 320 side A water cooling unit 340 is formed in which a water discharge hole 360 is formed and a cooling water passage 340 communicating with the water supply hole 350 and the water discharge hole 360 is formed to generate the heat generation unit 320 of the thermoelectric element 300. ), The cooling water supplied to the water cooling kit 330 is circulated by the circulation pump (not shown) and the connection hose 370.

However, in the above case, the structure of the cooling water channel 340 formed in the water cooling kit 330 has a disadvantage in that the heat generating portion of the thermoelectric element 300 cannot be cooled quickly according to the limit of thermal conductivity.

Accordingly, an object of the present invention is to provide a cooling apparatus that can be simplified in size and compact by cooling a cooling liquid using a thermoelectric element in a cooling apparatus equipped with a thermoelectric element in order to solve the conventional problems.

In addition, the present invention is another object of the present invention to provide a cooling device to increase the cooling efficiency and to smooth the flow of the cooling liquid by configuring a plurality of cooling liquid movement passage.

In addition, the present invention is another object of the present invention to provide a cooling device that can maximize the cooling efficiency by changing the diameter in accordance with the number of the coolant moving passage.

The object of the present invention is to provide a cooling device for cooling a cooling liquid circulating inside the apparatus to absorb heat generated in the apparatus, comprising: a pump for maintaining the flow of the cooling liquid in a constant direction; A cooling device connected to the coolant discharge port of the device and including a housing configured to constitute a plurality of moving passages of the coolant, and a thermoelectric element attached to the housing to cool the coolant; And a coolant storage tank configured to store the coolant, wherein the coolant movement passage is connected to a coolant outlet and is formed as a single pipe, and has an inlet portion having at least one coolant branch point and connected to the coolant branch point and a plurality of branch points. It is achieved by a cooling device having a thermoelectric element, characterized in that consisting of a branch portion formed of a plurality of pipes including an integrated portion connected to the branch portion and formed of one tube.

In addition, the housing is composed of a first and a second housing, at least one thermoelectric element is attached to one side of the first or second housing, the first and second housings are symmetrically coupled to the movement It is desirable to form passages.

In addition, the cooling device having a thermoelectric device according to the present invention includes a power supply unit for supplying power to the thermoelectric device; A temperature sensor for measuring a temperature of the cooling liquid; And a controller configured to control the power supply unit by extracting a temperature from the temperature sensor.

delete

Therefore, the cooling device having a thermoelectric element of the present invention has the advantage that the structure is simple by using a thermoelectric element, it is possible to minimize the volume.

In addition, the present invention has the effect of increasing the cooling efficiency and smooth the flow of the cooling liquid by configuring a plurality of cooling liquid moving passages of the cooling apparatus with a thermoelectric element.

In addition, according to the present invention, as the number of the coolant moving passages increases, the diameter of the coolant may be gradually reduced to uniformly disperse the coolant, and the cooling efficiency may be increased.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best describe their invention. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

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

Figure 4 is a block diagram of a magnetic field treatment device having a cooling device according to an embodiment of the present invention.

Referring to FIG. 4, the magnetic field therapy device having a cooling device includes a coil 400, a pump 410, a coolant storage tank 420, a cooling device 430, a power supply unit 440, a temperature sensor 450, and a controller ( 460).

The coil 400 has a characteristic of generating a magnetic field by receiving a current, and may treat a patient by using the magnetic field generated by the coil 400. In addition, the coil 400 generates heat together with the magnetic field. Therefore, the coil 400 is preferably manufactured in the form of a tube capable of circulating the coolant therein.

In addition, the coil 400 has a high corrosion resistance, good thermal or electrical conductivity, and is made of a copper tube having excellent mechanical properties, and its shape is most preferably made of a pancake type that draws a circle from the inside.

In addition, the coil 400 made of a copper tube may be applied to any shape that can efficiently generate a magnetic field even if it is not a pancake type.

The pump 410 extracts the coolant from the coolant storage tank 420 to inject and circulate the inside of the coil 200.

The coolant storage tank 420 stores a low temperature liquid coolant. In addition, the coolant storage tank 420 also stores a coolant in a liquid state circulated inside the coil 400.

The coolant uses a commercially available refrigerant oil such as silicone oil or transformer oil to prevent corrosion of the coil 400.

That is, the coolant stored in the coolant storage tank 420 absorbs heat generated from the coil 400 while circulating the inside of the coil 400 by the pump 410.

The cooling device 430 is a device for cooling the cooling liquid circulated through the coil 400. The cooling device 430 has a characteristic that the cooling performance is adjusted according to the power supplied from the power supply unit 440, that is, the amount of current.

Here, the coolant passing through the cooling device 430 is lowered in temperature, circulated to move to the coolant storage tank 420. The coolant storage tank 420 in which the coolant is stored is made of a material having a thermal insulation function to keep the temperature of the coolant at a low temperature by preventing the temperature from being changed by the surrounding environment.

The power supply unit 440 supplies power to the cooling device 430 to operate the cooling device.

Temperature sensor 450 is installed to measure the temperature of the cooling liquid absorbed heat generated from the coil 400, the position is preferably installed between the coil 400 and the cooling device 430.

The control unit 460 controls the power supply unit 440 by extracting the temperature of the cooling liquid measured by the temperature sensor 450. The controller 460 improves cooling performance by increasing the amount of current supplied to the cooling device 430 when the extracted temperature exceeds the first set temperature, and decreases the amount of current again when the temperature falls below a predetermined temperature, thereby reducing the temperature of the cooling liquid. Keep it constant.

In addition, a pipe connecting the coil 400, the pump 410, the coolant storage tank 420, and the cooling device 430 shown in FIG. 4 is a means for facilitating circulation of the coolant. It is preferable to use a PVC tube or a metal tube, which is a plastic tube that is excellent in chemical resistance and excellent in rust.

In addition, the pipe connecting the coil 400 and the cooling device 430 is preferably a metal pipe because the temperature of the coolant is high.

In the cooling device of the magnetic field treatment device shown in FIG. 4, when a high voltage and a high current are applied to the coil 400 made of a copper tube or a Litz wire, a magnetic field is generated and heat is generated. At this time, the current flows through the coil 400, but the coolant circulates inside or outside the coil. The coolant is stored in the coolant storage tank 420 and circulated by the pump 410.

Through the above process, the heat generated in the coil 400 is absorbed in the cooling liquid. As a result, the temperature of the cooling liquid rises and cooling is necessary. Therefore, the cooling device 430 is installed in the cooling liquid discharge portion of the coil 400 to cool the cooling liquid to lower the temperature. Here, the cooling device 430 is operated by receiving power from the power supply unit 440, and the cooling performance varies depending on the amount of power supplied, that is, the current. The control unit 460 adjusts the cooling performance of the cooling device 430 by extracting a temperature from the temperature sensor 450 installed between the coil 400 and the cooling device 430 to control the power supply unit 440.

In addition, the cooling device composed of the pump 410, the coolant storage tank 420 and the cooling device 430 according to an embodiment of the present invention is an electronic device or machine that requires a water-cooled cooling device using a coolant as well as a magnetic field treatment device. Applicable to the device and the like.

Figure 5a is a configuration diagram of a cooling device 500 according to an embodiment of the present invention, Figure 5b is a cross-sectional view of the cooling device 500 according to an embodiment of the present invention, Figure 5c is an embodiment of the present invention Side view of the cooling device 500 according to the.

5B is a cross-sectional view of the cooling device 500 illustrated in FIG. 5A taken along a dotted line of A-A ', and FIG. 5C is a side view of the cooling device 500 of FIG. 5A viewed from the right side.

5A to 5C, the cooling device 500 includes a thermoelectric element 510, a housing (not shown), a coolant movement passage (not shown), a water supply fastening part 570, a drainage fastening part 580, and a connection hose. 590 and the like.

Wherein the housing is composed of the first housing 520 and the second housing 530, the moving passage of the coolant generated by the combination of the first and second housings (520, 530) inlet, branch and integration It can be divided into three parts.

Here, the inflow portion is composed of the first movement passage 540, the branch portion is composed of the second movement passage 550, and the integrated portion is composed of the third movement passage 560.

The thermoelectric element 510 of the cooling device 500 is attached to the first housing 520 or the second housing 530 and serves to cool the coolant by receiving a current. One or more thermoelectric elements 510 may be configured according to the size or shape of the first housing 520 or the second housing 530, and the first, second, and third moving passages 540, 550, and 560 of the coolant may be used. Install so that it corresponds to the position of).

 Here, the thermoelectric element 510 is generally used for a device for cooling, and one side is cooled, and the other side is a device that generates heat, and has a merit of good cooling efficiency with no noise and a heat and electricity exchange system.

In addition, when the thermoelectric element 510 is composed of an N-type semiconductor element and a P-type semiconductor element and supplies DC power to both ends thereof, the thermoelectric element 510 absorbs (cools) heat from one terminal and heats the other terminal according to the direction of the current. The Peltier effect of emitting (heating) is generated, and the device is used to cool or warm a desired part, and thus the amount and direction of endotherm and heat generation can be adjusted according to the magnitude and direction of the current.

Although not shown, a heating device (not shown) is attached to the heating plate of the thermoelectric element 510. The heating device used in the thermoelectric element 510 may be air-cooled, water-cooled or combined (air-cooled + water-cooled). The heating device attached to the heating plate of the thermoelectric element 510 according to the present invention has a small volume and excellent performance. It is preferable to use a heat generator.

In addition, the first housing 520 and the second housing 530 constituting the housing of the cooling device 500 are symmetric with each other, and are coupled to the first, second, and third moving passages 540, 550, and 560. Form. As shown in FIG. 4, the first housing 520 and the second housing 530 are coupled to each other by forming a coupling hole in the center of each corner and the long surface.

The first and second housings 520 and 530 are preferably manufactured using aluminum having good thermal conductivity and easy molding, and other materials such as copper may be used.

The first moving passage 540 constituting the inlet is connected to the connection hose 590 to which the coolant discharged from the electronic device or the mechanical device moves and is formed as a single pipe. In addition, the first movement path 540 includes at least one branch point.

The second movement passage 550 constituting the branch portion is formed of a plurality of pipes connected to the branch point of the first movement passage 540.

The number and diameter of the second moving passage 550 is determined by the number of branch points of the first moving passage 540. Accordingly, the second moving passage 550 should be able to accommodate all of the inflow amount of the initial cooling liquid, and the number of branch points of the first moving passage 540 is as large as possible. Therefore, the second moving passage 540 has a wide contact area with the first and second housings 520 and 530, thereby maximizing cooling performance by the thermoelectric element 510.

The third moving passage 560 constituting the integrated part is formed of one pipe connected to the plurality of second moving passages 550 and is connected to the connection hose 590 connected to the coolant storage tank.

The first, second and third moving passages 540, 550, and 560 are connected to each other, and the coolant flows into the first moving passage 540 and is evenly branched into the plurality of second moving passages 550 at the branch point. . Then, the coolant passing through the second moving passage 550 is integrated into the lower portion and moves to the connection hose 590 connecting the coolant storage tank through the third moving passage 560 formed of one pipe.

In addition, the cooling device 500 may be connected to the connection hose 590 of an electronic device or a mechanical device such as a magnetic field therapy device by installing a water supply coupling part 570 in a portion where the coolant flows, and the coolant is discharged. The drainage fastening portion 580 is installed in the facilitating connection with the coolant storage tank.

6 is a view showing a cooling device 600 according to another embodiment of the present invention.

The cooling device 600 shown in FIG. 6 has the same configuration as the cooling device 500 shown in FIG. 5A.

However, the moving passage (not shown) of the coolant shown in FIG. 6 has a structure in which the diameter gradually decreases as the number of passages increases, so that the coolant is evenly distributed from side to side when the coolant flows into the cooling device 600.

The moving passage of the coolant is composed of an inlet, a branch, and an integrated part, the inlet is composed of a first moving path 620, and the branch is a second, third, and fourth moving path (630, 640, 650). It is configured, the integrated portion is composed of a fifth movement passage (660).

The first moving passage 620 constituting the inlet portion is connected to the connection hose 670 to which the coolant discharged from the electronic device or the mechanical device moves and is formed as a single pipe. In addition, the first movement passage 620 includes a coolant branch point.

The second movement passage 630 constituting the branch portion is composed of two pipes connected to the branch point of the first movement passage 620 and the second movement by the flow rate of the coolant per hour is the same as in the first movement passage 620 The diameter of the passage 630 is determined. In addition, the plurality of second movement passages 630 include two branch points.

The third movement passage 640 constituting the branch portion is composed of four pipes connected to the branch point of the second movement passage 630 through which the coolant divided into two branches passes. Here, the diameter of the third moving passage 640 is made smaller than the second moving passage 630, but the flow amount of the cooling liquid per hour is made to be the same as the second moving passage 630 to make the flow of the cooling liquid desired. In addition, the plurality of third movement paths 640 include four branch points.

The fourth moving passage 650 constituting the branch portion is composed of eight tubes connected to the third moving passage 640 through which the coolant divided into four branches passes. In this case, the diameter of the fourth moving passage 650 is smaller than that of the third moving passage 640, but the flow amount of the cooling liquid per hour is the same as that of the third moving passage 640, so that the cooling liquid flows.

The fifth moving passage 660 constituting the integrated part is formed as a single pipe into which the cooling liquid flowing through the plurality of fourth moving passages 650 is integrated, and is connected to the connection hose 670 connecting the cooling liquid storage tank.

The first, second, third, fourth, and fifth moving passages 620, 630, 640, 650, and 660 are connected to each other, and the coolant flows into the first moving passage 620 and consists of two pipes. It is distributed evenly to the second movement passage (630). Then, the coolant passing through the second moving passage 630 moves to the third moving passage 640 composed of four tubes. The divided coolant is divided into a fourth moving passage 650 consisting of eight tubes. In this way, the coolant is divided into eight branches, and the contact area with the housing of the cooling device 600 is widened, so that the cooling effect by the thermoelectric element 610 is improved.

Eight branch cooling liquid cooled by the thermoelectric element 610 is moved to the fifth moving passage 660 consisting of one tube to the connection hose 670 connecting the coolant storage tank.

The branch point of the branch of the coolant illustrated in FIG. 6 is larger in consideration of the diameter of the first moving passage 620 corresponding to the inlet, the number of the thermoelectric elements 610, the size of the housing of the cooling device 600, and the like. It may include a branching point of or fewer branching points of.

Although the present invention has been shown and described with reference to the preferred embodiments as described above, it is not limited to the above embodiments and those skilled in the art without departing from the spirit of the present invention. Various modifications and variations are possible without departing from the spirit of the present invention and equivalents of the claims to be described below.

INDUSTRIAL APPLICABILITY The present invention can be used for an electronic device or a mechanical device such as a magnetic field therapy device, a car, a refrigerator, a computer cooler, etc., which requires a water-cooled cooling device of a method of absorbing heat by circulating a coolant.

1 is a view showing a circuit of a conventional magnetic field therapy device,

2 is a block diagram showing a cooling apparatus of a conventional magnetic field treatment device,

3 is a perspective view of a water-cooled cooling apparatus by cooling a heat generating portion of a conventional thermoelectric element;

4 is a block diagram of a magnetic field therapy device having a cooling device according to an embodiment of the present invention;

Figure 5a is a block diagram of a cooling device according to an embodiment of the present invention,

Figure 5b is a cross-sectional view of a cooling apparatus according to an embodiment of the present invention,

Figure 5c is a side view of a cooling apparatus according to an embodiment of the present invention,

6 is a configuration diagram of a cooling apparatus according to another embodiment of the present invention.

          <Explanation of symbols for the main parts of the drawings>

500, 600: Cooling device 510, 610: Thermoelectric element

520: first housing 530: second housing

540, 620: first mobile passage 550, 630: second mobile passage

560, 640: third mobile passage 570: water supply connection part

580: drainage connection part 590, 670: connection hose

650: fourth moving passage 660: fifth moving passage

Claims (5)

A cooling device for cooling a cooling liquid circulated inside the device to absorb heat generated in the device, A pump for maintaining the flow of the cooling liquid in a constant direction; A cooling device connected to the coolant discharge port of the device and including a housing configured to constitute a plurality of moving passages of the coolant, and a thermoelectric element attached to the housing to cool the coolant; And Coolant storage tank for storing the coolant It includes, but the coolant moving passage is formed of a plurality of pipes connected to the coolant outlet and formed of one tube and having at least one coolant branch point and connected to the coolant branch point and a plurality of pipes including a plurality of branch points. Cooling device having a thermoelectric element, characterized in that consisting of a branch portion and an integrated portion connected to the branch portion and formed of one tube. delete delete The method of claim 1, The housing is composed of a first and a second housing, at least one thermoelectric element is attached to one side of the first or second housing, the first and second housings are symmetrically coupled to the mobile passage Cooling apparatus having a thermoelectric element, characterized in that forming. The method of claim 1, A power supply unit supplying power to the thermoelectric element; A temperature sensor for measuring a temperature of the cooling liquid; And Control unit for extracting the temperature from the temperature sensor to control the power supply unit Cooling apparatus having a thermoelectric element characterized in that it further comprises.

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