KR20200059582A - An Apparatus for Controlling a Temperature of a Thermoelement Module - Google Patents

Abstract

The present invention relates to a temperature control device for a thermoelectric element module. With the present invention, it is possible to adjust the level of cooling in accordance with the temperature of an adjustment target and the ambient temperature while separating control and drive power sources from each other. The temperature control device for a thermoelectric element module includes: a control power source (17) supplying electric power to a control module (11); a thermoelectric module (13) including a thermoelectric element and driven by a drive power source (12) separate from the control power source (17); a detection sensor (15) detecting the temperature of a cooling target (14); and an operation data unit (16) determining the level of operation of the thermoelectric module (13) based on the temperature information detected at the detection sensor (15). The operation of the drive power source (12) is controlled in accordance with a drive signal transmitted from the control module (11) and electrical separation from the drive power source (12) is performed.

Description

An Apparatus for Controlling a Temperature of a Thermoelement Module}

The present invention relates to a temperature control device of a thermoelectric element module, and specifically, to a temperature control device of a thermoelectric element module capable of adjusting a cooling level according to a temperature and an ambient temperature of an object to be regulated while separating a control power source and a driving power source.

Electronic cooling using heat absorption or heat generation of thermoelectric elements has been applied to various industrial fields, and such thermoelectric modules include a pn semiconductor, a heat insulating material, or a heat dissipation means. Electronic cooling technology like this is a medical device. It is applied to electronic or electric devices that generate heat according to computer parts or operations, and various technologies related to this are known.

Patent Publication No. 10-2011-0125723 discloses a technology capable of achieving temperature stabilization by removing the hunting phenomenon in an unstable temperature control range. Patent registration no. 10-1688888 discloses a temperature control system capable of stable temperature control in a control region in which the polarity of the thermoelectric element is switched. In addition, Patent Publication No. 10-2014-0143816 discloses a temperature control system in which a thermoelectric element is integrated with a temperature control system. In the process of cooling by a thermoelectric module including a thermoelectric element, it is necessary to adjust the cooling level according to the ambient temperature of the heating element, or to cool or heat in a limited range. In addition, since large power is required for driving the cooler, and the control module can operate at a relatively small power, it is advantageous to separate the driving power and the control power. However, the prior art does not disclose such a technique.

The present invention is to solve the problems of the prior art has the following purposes.

Prior Art 1: Patent Publication No. 10-2011-0125723 (Unisem, published on November 22, 2011) Electric chiller device and temperature control method thereof Prior Art 2: Patent Registration No. 10-1688888 (FST Co., Ltd. announced on December 22, 2016) Temperature control system using thermoelectric elements Prior Art 3: Patent Publication No. 10-2014-0143816 (Genstem Inc., published on December 17, 2014) Temperature control system with thermoelectric element

An object of the present invention is to provide a temperature control device of a thermoelectric element module capable of adjusting the cooling level according to the temperature and ambient temperature of the heating element while separating the control power and the driving power.

According to a preferred embodiment of the present invention, the temperature control device of the thermoelectric element module includes a control power supply for supplying power to the control module; A thermoelectric module including a thermoelectric element and driven by a driving power source independent of the control power source; A detection sensor that detects the temperature of the cooling target; And an operation data unit that determines an operation level of the thermoelectric module based on the temperature information detected by the detection sensor, wherein the driving power is controlled according to the driving signal transmitted from the control module and electrically separated from the driving power. do.

According to another suitable embodiment of the invention, the detection sensor detects the temperature of the cooling target and the ambient temperature and transmits it to the operation data unit.

According to another suitable embodiment of the present invention, the thermoelectric module includes a cooling module having a cooling channel formed therein.

According to another suitable embodiment of the present invention, the cooling passages are separated from each other by a separation wall while a plurality of curved paths are arranged in parallel, and each curved path has a different depth along the extending direction.

According to another suitable embodiment of the present invention, further comprising a comparator for determining cooling or heating according to the temperature detected by the detection sensor, the change time interval is set to change between cooling and heating do.

The temperature control device of the thermoelectric element module according to the present invention increases power consumption efficiency of a cooling device by electrically separating a driving power source requiring large power and a control power source capable of operating with relatively small power. In addition, the cooling performance is improved by adjusting the cooling or heating conditions according to the ambient temperature. The temperature control device according to the present invention may have a heat dissipation structure by a coolant such as a fan or a coolant or a coolant, and operate in a predetermined range while allowing cooling time to be controlled by adjusting the speed, pressure, or flow rate of the coolant By blocking this, various types of cooling control errors or safety accidents are prevented.

1 shows an embodiment of a temperature control device of a thermoelectric module according to the present invention.
2 shows an embodiment in which a temperature control device according to the present invention is applied.
3 shows an embodiment of a thermoelectric module applied to a temperature control device according to the present invention.
4 shows another embodiment of a temperature control device according to the present invention.

The present invention will be described in detail below with reference to the embodiments presented in the accompanying drawings, but the embodiments are intended for a clear understanding of the present invention and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, and are not described repeatedly unless necessary for understanding of the invention, and well-known components are briefly described or omitted, but the present invention It should not be understood as being excluded from the embodiment.

1 shows an embodiment of a temperature control device of a thermoelectric module according to the present invention.

1, the temperature control device of the thermoelectric module module includes a control power supply 17 for supplying power to the control module 11; A thermoelectric module 13 including a thermoelectric element and driven by a control power source 17 and an independent drive power source 12; A detection sensor 15 that detects the temperature of the cooling target 14; And an operation data unit 16 for determining the operation level of the thermoelectric module 13 based on the temperature information detected by the detection sensor 15, wherein the drive power supply 12 is transmitted from the control module 11 The operation is controlled according to the driving signal, and is electrically separated from the driving power supply 12.

The temperature control device may consist of a control portion and a driving portion, and the control portion determines whether or not the thermoelectric module 13 is operated, an operating method or an operating level based on the temperature detection information, and the driving portion is operated transmitted from the control portion It may have a function of operating the thermoelectric module 13 based on the start signal. The operation start signal may be a magnetic method or a relay method by a magnetic field generating element such as a photodiode, an electromagnet or a permanent magnet, but is not limited thereto.

The control portion may include a control module 11, an operation data unit 16 that determines the operation method of the thermoelectric module 13, and a control power supply 17 that supplies power to the control module 11. And the driving part of the thermoelectric module 13 and the temperature of the thermoelectric module 13 to be operated by the driving power supply 12 and the driving power supply 12 to cool the cooling target 14, and the heating element serving as the cooling target 14 It may include a detection sensor 15 for detecting the temperature or the ambient temperature. The control module 11 may be operated under a small current or small voltage condition, and power required for the operation of the control module 11 may be supplied by the control power supply 17. The control module 11 may have a function of determining whether the driving power source 12 is activated, and may transmit, for example, a light initiation signal, an electromagnetic initiation signal, or a similar operation initiation signal to the driving power source 12. The driving power supply 12 is operated independently of the control power supply 17 and can be electrically separated. Independently operated, regardless of whether or not the control power source 17 is operated, the driving power source 12 is driven to operate the thermoelectric module 13 or not. As described above, the control circuits of the control module 11 are protected by being electrically separated from each other and operated, thereby controlling the current leakage, such as leakage of the driving power supply 12, or electrical operation errors of similar driving parts. Safe operation of can be ensured. For the operation of the thermoelectric module 13, a large current or a large voltage is required, and the driving power supply 12 can supply power required for the operation of the thermoelectric module 13. The thermoelectric module 13 may include at least one thermoelectric element and heat dissipation means, and the thermoelectric element may be made of, for example, a pn semiconductor element. In addition, the heat dissipation means included in the thermoelectric module 13 may include, but is not limited to, a heat dissipation fin, a heat dissipation fan, or a cooling fluid. The thermoelectric module 13 may have a heat exchange function, and the heating element serving as the cooling target 14 may be cooled by the heat exchange function. The cooling target 14 may be a medical device having a therapeutic function by, for example, high-frequency generation, laser generation, or similar power consumption, and needs to be maintained in a predetermined temperature range. The thermoelectric module 13 may cool or heat the cooling target 14 according to the temperature or ambient conditions of the cooling target 14. The cooling target 14 may be a heat generating element of various types that is operated by power supply to generate heat, and heat exchange with the thermoelectric module 13 may be performed in various forms. For example, a medium such as cooling water or cooling oil may be cooled or heated to be guided to the cooling target 14 so that heat exchange can be performed. Depending on the temperature of the cooling target 14, the operating level of the thermoelectric module 13 may be adjusted, and the cooling or heating level may be adjusted. To this end, the temperature of the cooling target 14 may be detected by the detection sensor 15.

The temperature of the cooling target 14 or the heating element may be detected by the detection sensor 15, and optionally, the ambient temperature of the cooling target 14 may be detected. The temperature of the heating element may be a direct parameter that determines the operating level of the thermoelectric module 13, and the ambient temperature may be an indirect parameter that determines the operating level of the thermoelectric module 13. Specifically, it is determined whether the temperature of the heating element is within a predetermined range to determine whether the thermoelectric module 13 is operated. In addition, the ambient temperature is detected to determine the operation method of the thermoelectric module 13, for example, the circulation speed of the coolant or the coolant, the flow pressure, the flow amount, or the operation time of the thermoelectric element. The temperature or ambient temperature of the heating element detected by the detection sensor 15 may be transmitted to the operation data unit 16, and the operation data unit 16 determines the operation method of the thermoelectric module based on the detected temperature information It can be transmitted to the control module (11). The control module 11 may determine whether to operate the thermoelectric module 13 based on the transmitted operation data and transmit a driving signal to the driving power supply 12. In addition, the driving power supply 12 may start the operation of the thermoelectric module 13 based on the operation signal transmitted from the control module 11. Subsequently, the temperature information detected by the detection sensor 15 is transmitted to the control module 11 in the form of a feedback, and the control module 11 can maintain or stop the driving of the driving power source 12 based thereon.

Operation control of the thermoelectric module 13 according to the analysis of the detection information can be made in various ways and is not limited to the presented embodiment.

2 shows an embodiment in which a temperature control device according to the present invention is applied.

2, the control power supply 17 can be connected to the control module 11 by a photo coupler, a transistor element, a FET semiconductor element, a relay, or a similar signal generating unit 21. According to this, a signal amplification means such as a transistor may be included. The control module 11 can be operated based on a predetermined operating voltage, and can be electrically isolated from the driving power supply 12. The temperature of the heating element 23 to be cooled may be detected by the first temperature sensor 151, and the ambient temperature of the heating element 23 may be detected by the second temperature sensor 152 to the control module 11 Can be sent. The control module 11 may determine whether to operate the thermoelectric module 13 based on the transmitted information, and when the operation of the thermoelectric module 13 is determined, may transmit an operation start signal to the driving power supply 12. The switch unit 22 connecting the driving power supply 12 and the thermoelectric module 13 is operated according to the transmission of the operation start signal to the driving power supply 12, so that the operation of the thermoelectric module 13 can be started. Accordingly, the thermoelectric module 13 is operated to cool the heating element 23. The control module 11 may transmit an operation start signal through different paths according to cooling and heat generation, and the signal transmission may be digital or analog. Accordingly, the thermoelectric module 13 may cool or heat the heating element 23 according to an ambient temperature or an operating condition of the heating element 23. In addition, the cooling rate can be adjusted, and cooling or heating may be repeatedly performed within a predetermined range. As such, cooling and heating may be performed by the thermoelectric module 13, and a plurality of switch units 22 may be installed to operate according to respective conditions. Specifically, when the temperature is 25 ° C or higher, the cooling function is activated, and when the temperature is 0 ° C or lower, the heater function can be operated. The cooling or heating function may be achieved by a separate structure of the control power source 17 and the control module 11 that are operated independently, and a structure of the thermoelectric module 13 suitable for the control structure. In such an operating structure, if an operating condition is changed from heating to cooling or vice versa, an interval time may be set. Specifically, when the heating condition is changed from cooling to the heating furnace or vice versa, the working electrode of the thermoelectric element must be changed, so the voltage condition or the current condition must be set, and the change time interval for removing the effect according to the condition already operating This is set, and the time of change can be detected by appropriate detection means. For example, the change time interval may be 1 to 5 seconds, but is not limited thereto. The occurrence of an electrical error such as an electric short phenomenon can be prevented by a change time interval. The structure of the thermoelectric module 13 having such a function will be described below.

3 shows an embodiment of a thermoelectric module applied to a temperature control device according to the present invention.

Referring to FIG. 3, the thermoelectric module includes a cooling module 36 having a cooling channel 364 formed therein. In addition, the cooling passages 364 are separated from each other by a separation wall while a plurality of curved paths are arranged in parallel, and each curved path has a different depth along the extending direction.

The thermoelectric module 13 may cool or heat the target MT that is a heating element by a heat exchange method, and the thermoelectric module 13 may be made of a structure suitable for the purpose, structure, and operation type of the target MT Can be. For example, the thermoelectric module may allow heat exchange between the target MT and the thermoelectric element by flow of a fluid such as cooling water or cooling oil. To this end, the thermoelectric module 13 is in contact with the target MT, or a heat exchange block 33 that allows heat exchange to be made in a non-contact state; A cooling module 36 that absorbs or releases heat from the heat exchange block 33; And a heat dissipation fin unit 32 that dissipates heat emitted or absorbed from the thermoelectric element coupled to the heat exchange block 33 to the outside. Optionally, a heat dissipation fan 31 for dispersing heat induced by the heat dissipation fin unit 32 to the outside may be included. In addition, the first and second temperature sensors 151 and 152 that detect the target MT or the temperature around the target may be disposed at or around the target MT. The cooling module 36 may have a function of guiding a coolant such as cooling water or cooling oil to the inflow lines L11 and L12 connected to the target MT as a heating element. The cooling module 36 may be made of, for example, aluminum, aluminum alloy or similar metal having high thermal conductivity, and may include a flow path for the flow of refrigerant. Specifically, a cooling channel 364 for cooling water or a flow of cooling oil as a medium for heat exchange may be formed inside the cooling module 36. The cooling passages 364 may be separated from each other by a separation wall while a plurality of curved paths are arranged in parallel, and ends of different curved paths may be connected to each other. Each curved path may have a curved shape to increase the path length, and different curved paths may have a similar shape. The circumferential wall of the cooling passage 364 may be made of a thermally conductive material or similar material, and may be made of a double wall, if necessary. Inlet units 363a and outlet units 363b may be formed at both ends of the cooling channel 364, respectively. The inlet unit 363a may consist of a plurality of retention walls formed in a direction perpendicular to the direction of extension of each curved path of the cooling passage 364, and the outlet unit 363b is also the same as the inlet unit 363a. Or it can be made of a similar structure. A plurality of retention walls can be formed integrally with one end coupled to the circumferential wall and a curved path, and adjacent retention walls are respectively connected to the circumferential wall and the curved path, forming a gap with the other end and the retention wall and the curved path By doing so, a flow path can be formed. Cooling water introduced through the inlet 362a formed at one end of the inlet unit 363a may flow through a plurality of retention walls formed in the inlet unit 363a to be led to the cooling passage 364. The plurality of curved paths formed in the cooling channel 364 may have different depths along the length direction, and the depth change may be irregular. As a result, while the vortex is formed in the cooling channel 364, the residence time can be appropriately adjusted. At the same time, the contact area can be increased. In this way, the residence time is adjusted in the cooling passage 364 and the refrigerant made in a predetermined temperature range is discharged through the outlet 362b formed in the discharge unit 363b and is guided along the inflow lines L11 and L12 to target MT. Can be cooled or heated. Subsequently, the refrigerant that has undergone heat exchange with the target while flowing along the predetermined path at the target MT is discharged along the discharge lines L22 and L21 to flow into the inlet 362a and flow along the path described above. As described above, the flow paths formed in the inflow unit 363a and the discharge unit 363b have different directions in the flow paths formed in the cooling flow path 364, and thus the external pressure applied to the cooling water flow in the cooling flow path 364 is applied. Can be effectively controlled. In the presented embodiment, one part of the cooling module 36 is shown, but the cooling modules 36 having the same or similar structure are combined with each other to form a sealing structure, or the cooling module 36 is sealed by an appropriate sealing cover. Can be. Optionally, a plurality of heat dissipation holes 323 may be formed in the heat dissipation hole block 322, and a fluid or cooling gas, such as coolant and coolant, may be formed along with each heat dissipation hole 323 and the refrigerant in the cooling module 36. It can be induced to flow independently, and accordingly, heat transferred to the heat dissipation fin 321 can be quickly discharged to the outside to increase cooling or heating efficiency of the cooling module 36. The cooling passage 364 may be made of various structures capable of controlling the flow of the refrigerant or controlling the contact area, and is not limited to the presented embodiment. In addition, heat dissipation may be selectively improved by the heat dissipation fan 31. The flow of cooling water or cooling oil in the cooling module 36 can be adjusted in various ways and is not limited to the presented embodiment.

4 shows another embodiment of a temperature control device according to the present invention.

Referring to FIG. 4, the temperature control device of the thermoelectric module module includes a comparator 45 that determines cooling or heating according to the temperature detected by the detection sensor 15.

The temperature control device may include at least two independent power sources, for example, a first power source 41 for supplying power to the control module 11 and a second power source 43 for operation of the thermoelectric module 13 It may include. Temperature information from the first temperature sensor 151 or the second temperature sensor installed in the cooling target 14 may be transmitted to the detection signal processing unit 44, and the detection signal processing unit 44 is a cooling target corresponding to the heating element The temperature and ambient temperature of (14) can be converted and amplified into electrical signals and transmitted to the comparator 45. The comparator 45 may set the operation method of the thermoelectric module 13 in contrast to the temperature of the heating element and the ambient temperature. In addition, when an operation error of the cooling target 14 or the thermoelectric module 13 is detected, a blocking signal is generated through the blocking signal unit 451 and transmitted to the operation selection module 42 to be cooled to the cooling target 14 or the thermoelectric module 13 ) Can be stopped. The operation selection module 42 can determine heating or cooling, and a change time interval for changing between cooling and heating can be set. The comparison result of the comparator 45 can be transmitted to the operation data unit 46, and the operation data unit 46 determines whether the thermoelectric module 13 is operated, how the thermoelectric module 13 is operated, or the first temperature sensor 151 ) Can be determined, and operation data can be generated accordingly. The operation data may be transmitted to the control module 11, and the control module 11 may transmit an operation start signal to the second power source 43 through the operation selection module 42. The second power source 42 may operate the flow regulating unit 431 or the element regulating unit 432 based on the start signal transmitted from the operation selection module 42. The flow control unit 431 may, for example, operate a circulation pump (CR) to adjust the circulation rate of the cooling water or the operation level of the heat dissipation fan, and the method of operating the thermoelectric module 13 by the device control unit 432 Can be determined. Thereafter, the cooling target 14 may be maintained in a predetermined temperature range by circulating the cooling water or the cooling oil and operating the thermoelectric module 13. The operation of the thermoelectric module 13 can be adjusted in various ways and is not limited to the presented embodiment.

The temperature control device of the thermoelectric element module according to the present invention increases power consumption efficiency of a cooling device by electrically separating a driving power source requiring large power and a control power source capable of operating with relatively small power. In addition, the cooling performance is improved by adjusting the cooling or heating conditions according to the ambient temperature. The temperature control device according to the present invention may have a heat dissipation structure by a coolant such as a fan or a coolant or a coolant, and operate in a predetermined range while allowing cooling time to be controlled by adjusting the speed, pressure, or flow rate of the coolant By blocking this, various types of cooling control errors or safety accidents are prevented.

The present invention has been described in detail with reference to the presented embodiments, but those skilled in the art will be able to make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. . The present invention is not limited by such modified and modified inventions, but is limited by the appended claims.

11: control module 12: driving power
13: thermoelectric module 14: cooling target
15: detection sensor 16: operating data unit
17: control power supply 21: signal generating unit
22: switch unit 23: heating element
31: heat dissipation fan 32: heat dissipation fin unit
33: heat exchange block 36: cooling module
41, 43: 1st, 2nd power 42: Operation selection module
44: detection signal processing unit 45: comparator
46: operation data units 151, 152: first and second temperature sensors
321: radiating fin 322: radiating hole block
323: heat dissipation hole 362a: entrance
362b: outlet 363a: inlet unit
363b: exhaust unit 364: cooling passage
431: flow control unit 432: element control unit
451: Shut-off signal unit CR: Circulation pump
L11, L21: Inlet line MT: Target

Claims (5)

A control power supply 17 that supplies power to the control module 11;
A thermoelectric module 13 including a thermoelectric element and driven by a control power supply 17 and an independent drive power supply 12;
A detection sensor 15 that detects the temperature of the cooling target 14; And
And an operation data unit 16 for determining the operation level of the thermoelectric module 13 based on the temperature information detected by the detection sensor 15,
The driving power supply 12 is controlled in accordance with the driving signal transmitted from the control module 11, the temperature control device of the thermoelectric element module, characterized in that electrically separated from the driving power supply (12). The temperature control device of the thermoelectric element module according to claim 1, wherein the detection sensor (15) detects the temperature of the cooling target (14) and the ambient temperature and transmits it to the operation data unit (16). The method according to claim 1, Thermoelectric module (13) Temperature control device of a thermoelectric element module including a cooling module (36) with a cooling passage (364) formed therein. The method according to claim 3, The cooling flow path (364) is a plurality of curved paths are arranged in parallel and separated from each other by a separation wall, each curved path of the thermoelectric element module, characterized in that having a different depth along the extension direction Temperature control device. The method according to claim 1, further comprising a comparator (45) for determining the cooling (Cooling) or heating (heating) according to the temperature detected by the detection sensor 15, the change time interval is set to change between cooling and heating Temperature control device of the thermoelectric element module, characterized in that.

Images