KR102243237B1 - Cold and hot temperature control system of indoor ventilation system - Google Patents

Abstract

A cooling/heating supply device of an automatic air ventilation system includes a housing 210 having a predetermined shape; A plurality of partition walls 220 each formed in a vertical direction to transfer air introduced from the outside or air discharged from the inside in an S-shape while partitioning the inside of the housing 210 in a vertical direction; A partition plate installed in the horizontal direction inside the housing 210 to divide the interior of the housing 210 in which the plurality of partition walls 220 are formed in a vertical direction into an upper case 210a and a lower case 210b ( 240) and; First or third suction blower fans (231, 233) for forcibly inhaling external air and supplying it to the room along a preset path by the plurality of partition walls (220), and the lower case (210b) of the housing (210) Consists of a second or fourth discharge blowing fan (232, 234) installed on the outer or inner side of the unit and forcibly inhaling the internal air and discharging it to the outdoors along a preset path by the plurality of partition walls 220 And a blower 230 that becomes; A filter unit 250 for filtering out fine dust or foreign matter contained in outdoor air introduced from the outside according to the driving of the first suction fan 231; One or more main or sub cooling/heating control units 130a that heat-exchange the temperature of the air introduced from the outdoors and the air discharged from the room, or heat or cool the heat-exchanged air flowing in from the outside together with heat exchange to supply indoors. It is configured to include a cooling, heating control unit 130 having a 130b, 130c).

Description

Cooling and heating system of automatic air ventilation system {Cold and hot temperature control system of indoor ventilation system}

The present invention relates to a cooling and heating supply device of an automatic air ventilation system, and more particularly, to a cooling and heating supply device of an automatic air ventilation system capable of producing and supplying high-efficiency hot water in a short time even at a poor sub-zero temperature. .

In general, indoor air ventilation systems are installed in buildings to improve the quality of indoor air. In particular, the heat exchanger passes through a heat exchanger when discharging indoor air to the outside, and also passes through a heat exchanger when supplying outdoor air to the room. In this way, heat exchange between indoor air and outdoor air is performed to improve the efficiency of thermal energy.

In addition, the indoor air ventilation system sterilizes bacteria and removes harmful gases contained in the outdoor air, as well as removes harmful substances such as yellow dust, fine dust and pollen, and generates negative ions to benefit the human body. It is known as No. 10-0665475, "Pure Negative Ion Generation Ventilation Unit with Air Purification Function".

However, such a conventional negative ion generating ventilation unit has a type that is open to the outdoor air intake port and the indoor air discharge port, and the headwind may be introduced outdoors by strong wind, and such headwind has a problem that damages various filters and fans. .

In addition, when the ventilation unit is not operated, outside air may be introduced into the room through the outdoor air intake port and the indoor air discharge port. There is a problem to make.

Therefore, in order to solve this problem, the ventilation unit of indoor air of Korean Patent Publication No. 10-2012-0001982 is described, but the indoor air is purged and supplied to the room, and the air supplied to the room is preheated by a heat exchanger. Although there is an advantage of minimizing indoor heat loss, there is a problem in that there is no function of humidification and that the outdoor air is not effectively purified.

In addition, the conventional method cannot recover more than 50% at the maximum because air intersects theoretically and practically and recovers energy by heat exchange, and has a lower energy recovery rate in reality. In addition, there is a disadvantage that mold may occur due to condensation in the section where the outdoor air inlet pipe and the indoor air discharge pipe intersect each other.

Republic of Korea Patent Publication No. 10-0665475 Korean Patent Application Publication No. 10-2012-0001982

The present invention was conceived to solve the problems of the prior art described above, and an object of the present invention is to minimize the loss of cold heat or heat energy contained in the air discharged to the outside during ventilation. It is intended to provide a heating supply.

Another object of the present invention is to automatically apply temperature deviation control to automatically apply heat to the reaction surface of the thermoelectric element when the external temperature and the temperature of the indoor reaction surface of the thermoelectric element are out of a preset temperature range in the heating mode. It is to provide a ventilation system cooling and heating supply system.

A cooling/heating supply device of an automatic air ventilation system according to the present invention for achieving such an object comprises a housing having a predetermined shape and partitioning the interior of the housing in a vertical direction, and includes air introduced from the outside and air discharged from the inside. A plurality of partition walls provided vertically apart from each other in the housing so as to form an S-shaped path, and the interior of the housing in which the plurality of partition walls are formed in a vertical direction are divided into an upper case and a lower case. A partition plate installed in a horizontal direction inside, and installed on one side and the other side of the upper case of the housing, respectively, and a first suction that forcibly sucks outside air and supplies it to the room along a preset path by the plurality of partition walls. A second blowing fan and a third suction fan, respectively, installed on one side and the other side of the lower case of the housing, and forcibly inhaling internal air and discharging it to the outdoors along a preset path by a plurality of partition walls. A blower part having a discharge fan and a fourth discharge fan, located at the rear end of the first suction fan, but installed inside the housing, and flows from the outside according to the driving of the first suction fan A filter unit that filters fine dust or foreign matter contained in the outdoor air that is contained, and is installed between adjacent partition walls in the housing and between the upper case and the lower case of the housing, and air introduced from the outdoors and air discharged from the indoors. And a cooling/heating control unit including a sub cooling/heating control unit for exchanging the temperature of and a main cooling/heating control unit that heats or cools the heat-exchanged air introduced from the outside along with heat exchange and supplies it to the room.
The main cooling/heating control unit includes a rectangular case installed between the partition walls adjacent to each other in the housing and between the upper case and the lower case of the housing, and is disposed inside the case, and is opened in the partition plate. It is installed in a horizontal direction on one side, the working surface is arranged so that the reaction surface is located on the lower side, and the working surface is a thermoelectric element that performs heat generation or heat absorption, and the upper heat sink and the thermoelectric element surrounding the working surface of the thermoelectric element. It is composed of a lower heat dissipation plate surrounding the reaction surface, and is inserted between the heat dissipation element that radiates heat generated from the thermoelectric element to the outside, the upper heat dissipation plate on the working side of the heat dissipation element, or the lower heat dissipation plate on the reaction side of the heat dissipation element or installed in contact Is, an electric heating element that operates to automatically apply heat as needed, a temperature sensing unit that periodically senses the ambient temperature of the housing and the upper heat sink on the working side of the heat dissipation element and the lower heat sink on the reaction side of the heat dissipation element, and a power supply The supply unit controls the direction of the direct current applied to the main cooling/heating control unit to heat or cool the air passing through the thermoelectric element, and the upper heat dissipation plate surrounding the working surface of the thermoelectric element and the lower heat dissipating plate surrounding the reaction surface of the thermoelectric element The electric heating element is heated to control the temperature difference when the temperature difference of is out of the preset temperature range or when the temperature difference between the surrounding of the housing and the lower heat sink surrounding the reaction surface of the thermoelectric element is out of a preset temperature range. It characterized in that it comprises a control unit to execute.
The control unit includes an A/D converter for converting a temperature value sensed in the form of an analog signal from the first to third temperature sensors of the temperature sensing unit into a digital signal, and a positive frequency converter for converting a direction of a direct current applied to the thermoelectric element In order to control the direction of the output current of the forward/reverse switching circuit according to the temperature values detected by the first to third temperature sensors according to the temperature value set by the switching circuit and the control unit, or to heat the electric heating element, a power supply unit It characterized in that it comprises a microprocessor to control.
The microprocessor of the control unit controls the temperature of the reaction surface of the thermoelectric element to be about 2° C. to about 3° C. lower than the ambient temperature of the housing so that heat absorption is smoothly performed when the ambient temperature of the housing is an image, and the housing When the ambient temperature of is below zero, the ambient temperature of the housing is ignored, and the temperature deviation is controlled so that condensation or condensation of water vapor does not occur on the reaction surface of the thermoelectric element.

delete

The cooling/heating supply device of the automatic air ventilation system according to the present invention can minimize the loss of cold heat or hot heat energy contained in the air discharged to the outside during ventilation, and thus the energy lost using the thermoelectric element (cold heat, Heat) can be recovered more than 90%, and depending on the situation and purpose, it is possible to supply cold air and hot products by adding cold heat and heat, as well as assisting or replacing the functions of boilers and air conditioners.

In addition, in the heating mode, when the external temperature and the temperature of the reaction surface of the thermoelectric element are out of the preset temperature range, the temperature deviation control that automatically applies heat to the reaction surface of the thermoelectric element can be executed. It provides the effect of making high-efficiency warm air in time.

In addition, when the heating or cooling mode is operated, electromagnetic waves are not exposed, vibration and noise can be reduced, and since the electronic cooling or heating method is used, the temperature response (immediate cooling or heating) is good. It has a relatively better effect than conventional products.

1A is a plan view of a cooling/heating supply apparatus of an automatic air ventilation system according to a preferred embodiment of the present invention;
1B is a cross-sectional view of a cooling and heating supply apparatus of an automatic air ventilation system according to a preferred embodiment of the present invention;
2A and 2B are exploded perspective views of a cooling/heating control unit of a cooling/heating supply device of an automatic air ventilation system according to a preferred embodiment of the present invention;
3 is a block diagram illustrating a circuit connection relationship between a cooling and heating supply device of an automatic air ventilation system according to a preferred embodiment of the present invention;
4 is a block diagram of a control unit of a cooling/heating supply device of an automatic air ventilation system according to a preferred embodiment of the present invention.

Hereinafter, a configuration and operation of a cooling/heating supply apparatus of an automatic air ventilation system according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1A is a plan view of a cooling/heating supply apparatus of an automatic air ventilation system according to a preferred embodiment of the present invention; 1B is a cross-sectional view of a cooling and heating supply apparatus of an automatic air ventilation system according to a preferred embodiment of the present invention; 2A and 2B are exploded perspective views of a cooling/heating control unit of a cooling/heating supply device of an automatic air ventilation system according to a preferred embodiment of the present invention.

1 and 2, the indoor ventilation system according to a preferred embodiment of the present invention includes a rectangular housing 210 and an interior of the housing 210 while partitioning the interior of the housing 210 in a vertical direction, A plurality of partition walls 220 each formed in the vertical direction to transport the air discharged from the S-shape, and the interior of the housing 210 in which the plurality of partition walls 220 are formed in the vertical direction is connected to the upper case 210a and The partition plate 240 installed in the horizontal direction inside the housing 210 to partition into the lower case 210b and the outer or inner surface of the upper case 210a of the housing 210 are respectively installed to The first or third suction blower fans 231 and 233 forcibly suctioning and supplying them to the room along a preset path by the plurality of partition walls 220, and the outer surface of the lower case 210b of the housing 210 or Blowing unit 230 composed of second or fourth discharge blowing fans 232 and 234 respectively installed on the inner side and forcibly inhaling the internal air and discharging it to the outdoors along a preset path by a plurality of partition walls 220 ), and is installed inside the housing 210 located at the rear end of the first suction fan 231, the fine particles contained in the outdoor air introduced from the outside according to the driving of the first suction fan 231 It is installed between the filter unit 250 for filtering dust or foreign matter, the partition walls 220 adjacent to each other in the housing 210, and between the upper case 210a and the lower case 210b of the housing 210, One or more main or sub cooling/heating control units 130a that heat-exchange the temperature of the air introduced from the outdoors and the air discharged from the room, or heat or cool the heat-exchanged air flowing in from the outside together with heat exchange to supply indoors. It consists of a cooling, heating control unit 130 having a 130b, 130c).

Here, the main cooling and heating control unit 130a is, as shown in FIGS. 2A and 3, between the partition walls 220 adjacent to each other in the housing 210 and the upper case 210a of the housing 210 A rectangular case 131 installed between the and the lower case 210b, and the partition plate 240 are installed horizontally in an open position extending from the installation position, and the action surface S3 is a reaction surface on the upper side. (S1) is arranged to be located at the lower side, the working surface (S3) under the control of the control unit 170 is a thermoelectric element 133 performing a heat generation or heat absorption operation, and the working surface (S3) of the thermoelectric element 133 The heat dissipation element 135 is composed of an upper heat dissipation plate 135a surrounding the and a lower heat dissipation plate 135b surrounding the reaction surface S1 of the thermoelectric element 133, and radiates heat generated from the thermoelectric element 133 to the outside. , It is inserted between the upper heat sink 135a on the acting side of the heat dissipation element 135 or the lower heat sink 135b on the reaction side of the heat dissipation element 135 or is installed to be in surface contact, and automatically applies heat as needed. Periodically sensing the ambient temperature of the electric heating element 137 and the upper heat sink 135a on the acting side of the heat dissipation element 135 or the lower heat sink 135b on the reaction side of the heat dissipation element 135 and the housing 210 It heats or cools the air passing through the thermoelectric element 133 by controlling the direction of the direct current applied from the temperature sensing unit 150 and the power supply unit 180 to the main cooling/heating control unit 130a. When the temperature difference between the upper heat sink 135a surrounding the working surface S3 of the element 133 and the lower heat sink 135b surrounding the reaction surface S1 of the thermoelectric element 133 is outside the preset temperature range, or the housing When the temperature difference between the periphery of 210 and the lower heat sink 135b surrounding the reaction surface S1 of the thermoelectric element 133 is out of a preset temperature range, the electric heating element 137 is heated to perform temperature deviation control. It consists of a control unit 170.

In addition, the sub-cooling and heating control units (130b, 130c), as shown in Figure 2b, the case 131 of a square shape, the upper heat sink (135a) installed at the upper end and the lower heat sink (135b) installed at the lower end Consisting of, it is composed of a heat dissipation element 135 for exchanging the temperature of the air introduced from the outdoors and the air discharged from the room.

Here, the interior of the housing 210 may be partitioned in a vertical direction to be formed as an upper housing and a lower housing, or may be formed as a left or right housing according to an arrangement method.

In addition, the thermoelectric element 133 is also expressed as a Peltier element, a thermoelectric conversion element, a semi-equal element, a Peltier element, a temperature module, and a TEC, and is a semiconductor element that allows cooling, heating, and temperature control freely by direct current. (1) Temperature difference occurs on both sides of the device by passing a direct current to the device, (2) heat absorption occurs on the low-temperature side and heat is generated on the high-temperature side, pushing heat from the low-temperature side to the high-temperature side of the thermoelectric device. That is, it acts as a heat pump, and (3) changing the direction of the heat pumped by simply changing the polarity of the current and also changing the size of the current, it is possible to change the amount of heat to be pumped.

In addition, the electric heating element 137 can be selected from an electric resistance heating wire, a PCT heating element, a coil heater, an input heater, a cartridge heater, a casting heater, a seed heater, a halogen heater, an infrared heater, a fin heater, a ceramic band heater, a flange heater, etc. It can be used, and all heating elements using electricity are applicable.

In addition, the temperature sensing unit 150 includes a first temperature sensing sensor 151 installed on the upper heat sink 135a surrounding the working surface S3 of the thermoelectric element 133, and the reaction surface S1 of the thermoelectric element 133 It is composed of a second temperature sensor 153 installed on the lower heat sink (135b) surrounding the, and a third temperature sensor 153 installed on the outer surface of the housing 210, the top and bottom of the thermoelectric element 133 It is preferable to periodically measure the air temperature and the ambient temperature of the housing 210 and transmit them to the control unit 170, respectively.

Meanwhile, as shown in FIG. 4, the control unit 170 includes an A/D converter 171 for converting a temperature value sensed in the form of an analog signal by the first to third temperature sensors 151, 153, and 155 into a digital signal, and , The forward/reverse conversion circuit 172 for converting the direction of the DC current applied to the thermoelectric element 133 under the control of the controller 170, and the first to third temperature sensors 151, 153, 155 under the control of the controller 170. ) To the microprocessor 173 that controls the direction of the output current of the forward/reverse conversion circuit 172 to correspond to the temperature value detected in), or controls the operation of the power supply unit 180 to heat the electric heating body 137. It is composed.

Here, the microprocessor 173 of the control unit 170, when the ambient temperature of the housing 210 is an image, the temperature of the reaction surface (S1) of the thermoelectric element 133 is around the housing 210 so that the heat absorption is smooth. It is controlled to be relatively 2~3℃ lower than the temperature, and when the ambient temperature of the housing 210 is below zero, condensation or condensation of water vapor is generated on the reaction surface S1 of the thermoelectric element 133, ignoring the ambient temperature of the housing. It is desirable to control the temperature deviation so that it does not occur.

In addition, the power supply unit 180 may use a battery provided in the housing 210 or use a separate external power supply device.

Hereinafter, an operation of a cooling/heating supply apparatus of an automatic air ventilation system according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

(1) Initial state setting

In order to use the cooling/heating supply device of the automatic air ventilation system according to the present invention, the thermoelectric element 133, the blowing unit 230, and the temperature sensing unit 150 are controlled by the control unit 170 in the power supply unit 180. , It is determined whether the moisture sensing unit 160 can be operated, and if it is determined as a normal state, the normal state is indicated by using a status indicator mounted on the outer surface of the housing 210.

(2) Operation mode setting

When the current state is determined to be a normal state, the microprocessor 173 of the control unit 170 may execute a heating mode or a cooling mode according to a temperature sensing value periodically transmitted from the temperature sensing unit 150, and Accordingly, the intensity of each heating mode or cooling mode can also be adjusted.

(3) Heating mode

The microprocessor 173 of the control unit 170 first drives the first suction blower fan 231 or the third suction blower fan 233 of the blower unit 230 to form the upper case 210a of the housing 210. Inhaling the external air through the external air inlet formed at the outer end of the housing 210, while flowing into the interior through the transfer path formed inside the housing 210, the second discharge blowing fan 232 or the fourth Drives the exhaust blower fan 234 to inhale the internal air through the internal air inlet formed at the inner end of the lower case 210b of the housing 210, and enters the inside through the transfer path formed inside the housing 210 The outgoing and incoming heat exchange heat with each other.

Subsequently, the microprocessor 173 of the control unit 170 controls the forward/reverse conversion circuit 172 to change the direction of the current entering the thermoelectric element 133 from the power supply unit 180 to the action surface (S3) of the thermoelectric element 133 A direct current in a preset direction (+ or-direction) is applied to the thermoelectric element 133 so as to face the upward direction.

In this case, the control unit 170 may adjust the intensity of the preset heating mode by adjusting the intensity of the voltage and current applied to the thermoelectric element 133 to correspond to the intensity of the heating mode operated by the manager.

Accordingly, since the working surface S3 of the thermoelectric element 133 of the cooling/heating control unit 130 emits heat and the reaction surface S1 of the thermoelectric element 133 absorbs heat, the thermoelectric element 133 The heat-exchanged air passing through the upper heat sink 135a of the heat dissipation element 135 installed on the working surface (S3) of the heat exchanger can be heated, so that the heated air is heated through the indoor air outlet formed in the housing 210. Can be discharged.

Meanwhile, when the current mode is the heating mode, the microprocessor 173 of the control unit 170 includes a first temperature sensor 151 installed on the upper heat sink 135a surrounding the working surface S3 of the thermoelectric element 133 and , The temperature sensing value sensed by the second temperature sensor 153 installed on the lower heat sink 135b surrounding the reaction surface S1 of the thermoelectric element 133 or the lower side surrounding the reaction surface S1 of the thermoelectric element 133 By periodically receiving the temperature sensing values of the second temperature sensing sensor 153 installed on the heat sink 135b and the third temperature sensing sensor 153 installed on the outer surface of the housing 210, the difference between the two temperature values is preset. If the temperature range is not exceeded, the heat absorption function of the lower heat sink 135b of the heat dissipation element 135 is determined to be in a normal state and the electric heating element 137 is not operated, but the difference between the two temperature values falls within the preset temperature range. If it exceeds, it is determined that the heat absorbing function of the lower heat sink 135b of the heat dissipating element 135 is not normal, such as a situation in which condensation occurs or condensation of water vapor occurs, and the electric heating element 137 is controlled to be operated.

That is, when the outside temperature is an image, the control unit 170 controls the surrounding of the housing 210 so that the temperature of the lower heat sink 135b of the heat dissipation element 135 on the working surface S3 of the thermoelectric element 133 is smoothly absorbed. The lower heat sink of the heat dissipation element 135 mounted on the reaction surface (S1) side of the thermoelectric element 133 is controlled to be relatively lower than the outside temperature by 2~3℃, and when the outside temperature is below zero, the outside temperature is ignored. It is desirable to operate to control the temperature so that no condensation or condensation of water vapor occurs in 135b).

(3) Cooling mode

The microprocessor 173 of the control unit 170 first drives the second discharge blowing fan 232 or the fourth discharge blowing fan 234 of the blowing unit 230 to form the lower case 210b of the housing 210. Inhaling indoor air through the indoor air inlet formed at the inner end of the housing 210 and flowing into the interior through the transfer path formed inside the housing 210, the first suction fan 231 or the fourth Drives the exhaust blower fan 234 to inhale the internal air through the internal air inlet formed at the inner end of the lower case 210b of the housing 210 and discharge it to the outside through a transfer path formed inside the housing 210 The outgoing and incoming heat exchange heat with each other.

Subsequently, the microprocessor 173 of the control unit 170 controls the forward and reverse switching circuit 172 to change the direction of the current entering the thermoelectric element 133 from the power supply unit 180 to the reaction surface (S3) of the thermoelectric element 133 A direct current in a preset direction (+ or-direction) is applied to the thermoelectric element 133 so as to face the upward direction.

In this case, the controller 170 may adjust the intensity of the preset heating mode by adjusting the intensity of the voltage and current applied to the thermoelectric element 133 to correspond to the intensity of the cooling mode operated by the manager.

Accordingly, the reaction surface S3 of the thermoelectric element 133 of the cooling/heating control unit 130 dissipates heat while the working surface S1 of the thermoelectric element 133 absorbs heat, so that the thermoelectric element 133 The heat-exchanged air installed on the working surface S3 of may be cooled, so that the cooled cold air may be discharged through the indoor air outlet formed in the housing 210.

The embodiments of the present invention disclosed in the specification and drawings described above are merely specific examples to aid understanding, and are not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is apparent to those of ordinary skill in the art that other modifications based on the technical idea of the present invention may be implemented.

110: housing 111: indoor air inlet
113: indoor air outlet 130: cooling, heating control unit
133: thermoelectric element 135: heat sink
135a: upper heat sink 135b: lower heat sink
137: electric heating body 150: temperature sensing unit
151, 153, 155: first to third temperature sensor
160: moisture detection unit
170: control unit 171: A/D converter
172: forward and reverse switching circuit 173: microprocessor
180: power supply 210: housing
220: bulkhead 230: air blower
240: partition plate 250: filter unit

Claims (4)

A housing 210 having a predetermined shape;
Dividing the inside of the housing 210 in a vertical direction, a plurality of air introduced from the outside and air discharged from the inside are vertically spaced apart from each other in the interior of the housing 210 so as to form an S-shaped path. The partition wall 220;
A partition plate 240 installed in a horizontal direction inside the housing 210 to divide the interior of the housing 210 in which the plurality of partition walls 220 are formed in a vertical direction into an upper case 210a and a lower case 210b. );
A first suction installed on one side and the other side of the upper case 210a of the housing 210, respectively, and forcibly suctioning outside air and supplying it to the room along a preset path by the plurality of partition walls 220 It is installed on one side and the other side of the lower case 210b of the housing 210 and the third blowing fan 231 and the third suction blowing fan 233, and a plurality of partition walls ( A blower 230 having a second discharge blower fan 232 and a fourth discharge blower fan 234 discharged to the outdoors along a path preset by 220;
Located at the rear end of the first suction fan 231 but installed inside the housing 210, fine dust contained in outdoor air introduced from the outside by the driving of the first suction fan 231 A filter unit 250 for filtering out foreign substances; And
It is installed between the partition walls 220 adjacent to each other in the housing 210 and between the upper case 210a and the lower case 210b of the housing 210. Cooling, which includes sub-cooling and heating control units 130b and 130c for exchanging temperature, and a main cooling/heating control unit 130a that heats or cools the heat-exchanged air introduced from the outside along with heat exchange and supplies it to the room. Heating control unit 130; Including,
The main cooling and heating control unit (130a),
A rectangular case 131 installed between the partition walls 220 adjacent to each other in the housing 210 and between the upper case 210a and the lower case 210b of the housing 210;
Arranged inside the case 131, installed in a horizontal direction on one side of the partition plate 240, the action surface (S3) is arranged to be located at the upper side and the reaction surface (S1) is located at the lower side. A thermoelectric element 133 in which the surface S3 performs heat generation or heat absorption;
Consisting of an upper heat sink 135a surrounding the working surface S3 of the thermoelectric element 133 and a lower heat dissipating plate 135b surrounding the reaction surface S1 of the thermoelectric element 133, A heat dissipation element 135 that radiates heat to the outside;
It is inserted between the upper heat sink 135a on the acting side of the heat dissipation element 135 or the lower heat sink 135b on the reaction side of the heat dissipation element 135 or is installed to be in surface contact, and automatically applies heat as needed. An electric heating element 137;
A temperature sensing unit 150 for periodically sensing the ambient temperature of the upper heat sink 135a on the working side of the heat dissipation element 135, the lower heat sink 135b on the reaction side of the heat dissipation element 135, and the housing 210; And
The power supply unit 180 controls the direction of the direct current applied to the main cooling/heating control unit 130a to heat or cool the air passing through the thermoelectric element 133, and the action surface of the thermoelectric element 133 ( When the temperature difference between the upper heat sink 135a surrounding S3) and the lower heat sink 135b surrounding the reaction surface S1 of the thermoelectric element 133 is outside a preset temperature range, or the surroundings of the housing 210 and the thermoelectric When the temperature difference of the lower heat sink 135b surrounding the reaction surface S1 of the element 133 is out of a preset temperature range, the control unit 170 heats the electric heating element 137 to perform temperature deviation control. ; Cooling and heating supply device of an automatic air ventilation system comprising a.
delete The method of claim 1,
The control unit 170,
An A/D converter 171 for converting a temperature value sensed in the form of an analog signal by the first to third temperature sensors (151, 153, 153) of the temperature sensing unit 150 into a digital signal;
A forward and reverse conversion circuit 172 for converting a direction of a direct current applied to the thermoelectric element 133; And
The direction of the output current of the forward/reverse switching circuit 172 is controlled according to the temperature values detected by the first to third temperature sensors (151, 153, 155) according to the temperature value set by the control unit 170, or the electric heating element ( A cooling and heating supply device for an automatic air ventilation system, comprising: a microprocessor 173 that controls the power supply unit 180 to heat the 137).
The method of claim 3,
The microprocessor 173 of the control unit 170,
When the ambient temperature of the housing 210 is an image, the temperature of the reaction surface S1 of the thermoelectric element 133 is controlled to be 2℃ to 3℃ lower than the ambient temperature of the housing 210 so that heat absorption is smooth. And, when the ambient temperature of the housing 210 is below zero, the ambient temperature of the housing 210 is ignored, and the temperature deviation is controlled so that condensation or condensation of water vapor does not occur on the reaction surface S1 of the thermoelectric element 133. Cooling and heating supply device of an automatic air ventilation system, characterized in that.

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