KR20150084425A - System for supplying hot water using solar enegy - Google Patents

Abstract

The present invention relates to a solar hot water system capable of operating in a stable system by having an automatic supplement function of a heating medium. The solar hot water system comprises: a solar collector (100); a heating medium circulation pipe (200) to form a close circuit wherein a heating medium is circulated by connecting an inlet and an outlet of the solar collector (100); and a storage tank (300) equipped to allow a part of the heating medium circulation pipe (200) to pass around inside, and to exchange heat between hot water accommodated inside and the heating medium heated by solar heat. The heating medium circulation pipe (200) includes: a heat collection circulation pump (210) to press the heating medium in order to be circulated; and a steam-water separator (220) equipped in an inlet of the heat collection circulation pump (210) having a water level sensor (221) to sense a water level of the heating medium, and an air vent (222) to separate and discharge air contained in the heating medium. In a heating medium tank (230), a heating medium supplement pipe (240) is branched on one side of the heating medium circulation pipe (200) and connected. In the heating medium supplement pipe (240), a booster pump (250) to press the heating medium stored in the heating medium tank (230) toward the heating medium circulation pipe (200), and a check valve (260) equipped in an outlet of a booster pump (250) to prevent the heating medium from back flowing towards the heating medium tank (230) are equipped. Moreover, comprised is a control part (600) to control for controlling booster pump (250) to be operated when the water level of the heating medium is low based on a water level of the heating medium sensed by the water level sensor (221).

Description

SYSTEM FOR SUPPLYING HOT WATER USING SOLAR ENGY

The present invention relates to a solar hot water system, and more particularly, to a solar hot water system capable of performing a stable operation of a system by smoothly circulating a heat medium flowing along a heat medium circulation pipe, .

As is well known, hot water systems used for heating and hot water supply have been developed in the form of boiler systems using fuel such as briquette, oil, gas and electricity. However, a hot water system using solar energy is being developed as a means of depletion of fossil fuels and securing alternative energy resources, which are getting worse.

1 is a block diagram of a conventional solar hot water system.

The solar hot water system according to the related art includes a solar heat collector 10, a heat medium circulation pipe 20 through which the heat medium circulating therethrough is circulated, a heat exchanger 30 through which the heat medium circulation pipe 20 passes, A hot water circulation pipe 50 installed in the heat storage tank 40 so that the hot water in the heat storage tank 40 passes through the inside of the heat exchanger 30 and exchanges heat with the heating medium, A boiler 70 for heating and supplying the hot water in the heat storage tank 40 when the solar energy is lacking, and a controller 70 for controlling the overall operation of the hot water system, (80).

The solar collector 10 collects solar heat and transfers the solar heat to the heating medium passing through the inside thereof. The collector side temperature sensor 11 for detecting the temperature of the heating medium heated by the solar heat is provided on the discharge side.

The heat medium circulation pipe (20) is provided with a heat medium circulation pump (21) for pressure feeding the heat medium to circulate the heat medium and an expansion tank (22) for absorbing the pressure change of the heat medium. The heat medium supplement pipe 24 connected to the heat medium supplement tank 23 is branched at one side of the heat medium circulation pipe 20 in the structure for replenishing the heat medium at the time of the lack of the heat medium, A pump 25 is provided. A discharge pipe 26 branched to be connected to the heat medium replenishing tank 23 is connected to the heat medium circulation pipe 20 and a safety valve 27 for preventing an abrupt pressure rise of the heat medium is connected to the discharge pipe 26 Respectively. The heating medium circulation pipe 20 is provided with a pressure gauge 28 for measuring the pressure of the heating medium and is provided with a thermometer for measuring the temperature of the heating medium before and after the passage of the heat exchanger 20 and various valves for interrupting the flow of the heating medium .

The heat medium circulation pipe 20 and the hot water circulation pipe 50 pass through the inside of the heat exchanger 30 and the heat medium flowing along the inside of the heat medium circulation pipe 20 and the inside of the hot water circulation pipe 50 A heat transfer fluid for heat exchange is filled between the hot water flowing.

The storage tank 40 is provided with a storage tank upper temperature sensor 41 and a storage tank lower temperature sensor 42 for sensing the temperature of the hot water located in the upper and lower parts. A direct water supply pipe 43 is provided below the storage tank 40, And the drain pipe 44 are connected to each other.

The hot water circulation pipe 50 is provided with a hot water circulation pump 51 for feeding the hot water stored in the heat storage tank 40 to circulate along the hot water circulation pipe 50 and a hot water circulating pump 51 for circulating hot water before and after passing through the heat exchanger 20 A thermometer for measurement, and various valves for interrupting the flow of hot water.

One end of the hot water supply pipe 60 is connected to an upper portion of the heat storage tank 40 and extends to the power reception 62. The hot water supply pipe 60 is connected to an inlet of the boiler 70 and a direct water supply pipe 43 A first connecting pipe 71 is installed and a second connecting pipe 72 is installed between the outlet of the boiler 70 and the hot water supply pipe 60. A three-way valve 61 for switching the flow path of hot water is provided at a branch point where the hot water supply pipe 60 and the first connection pipe 71 meet.

When the temperature difference between the temperature measured by the collector temperature sensor 11 and the temperature of the hot water measured by the regenerator bottom temperature sensor 42 is equal to or higher than the set temperature difference, the control unit 80 controls the heating medium circulation pump 21, Way valve 51 is operated so as to control the flow path switching operation of the three-way valve 61 and the operation of the boiler 70 by comparing the temperature measured by the temperature sensor 41 with the set temperature value .

In the conventional solar hot water system configured as described above, it is checked whether the heating medium is insufficient through the pressure value measured by the pressure gauge 28. When the measured pressure value is measured at a value smaller than the reference pressure value, And the heat medium replenishing pump 25 is operated to replenish the heat medium.

However, when the solar radiation is supplied, the heating medium is thermally expanded even when the heating medium is insufficient. Therefore, it is difficult to precisely determine whether the heating medium is insufficient based on the pressure measurement value detected by the pressure gauge 28, and the heating medium is circulated in a state in which the heating medium is insufficient The heat medium circulation pump 21 is overloaded and the solar hot water system can not be stably operated.

In the related art, the patent document 10-1322555 discloses a configuration in which the heating medium is configured to flow through the heating medium tank, and when the heating medium is insufficient, the heating medium is replenished and supplied through the water pipe by checking the water level of the heating medium tank. Patent Document 10-1168542 discloses a configuration in which a pressurizing pump is operated to supplement and supply a heat medium stored in a heat medium tank when the heat medium is in a shortage. However, these prior art documents disclose a configuration in which a heat medium is insufficiently detected, There is no constitution for this purpose.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for controlling a circulation of a heat medium by providing an automatic replenishment function of a heat medium to accurately detect a shortage state of a heat medium flowing through the heat medium circulation pipe, And to provide a solar hot water system capable of stable operation of the system.

In order to achieve the above object, the present invention provides a solar hot water system comprising: a solar collector (100) for collecting solar heat and heating a heat medium; A heat medium circulation pipe 200 connecting the outlet side and the inlet side of the solar collector 100 to constitute a closed circuit through which the heat medium circulates; And a heat storage tank (300) having a part of the heat medium circulation pipe (200) through which heat is exchanged between the heat medium heated by the solar heat and the hot water stored therein, wherein the heat medium circulation pipe ) Includes a heat collecting circulation pump 210 for feeding and circulating the heat medium in circulation and a water level sensor 221 provided at the inlet side of the heat collecting circulation pump 210 for sensing the water level of the heat medium, A water heater separator 220 including an air vent 222 for discharging water is provided at one side of the heating medium circulation pipe 200 and a heating medium supplement pipe 240 is branched at a side of the heating medium circulation pipe 200 to be connected to a heating medium tank 230, The pipe 240 is provided with a pressurizing pump 250 that pressurizes and conveys the heat medium stored in the heat medium tank 230 toward the heat medium circulation pipe 200 and a heat medium provided at the outlet side of the pressurization pump 250, 230) And a control unit 600 for controlling the operation of the pressurization pump 250 based on the level of the heat medium sensed by the water level sensor 221 when the heat medium is low, do.

The inlet side heat medium circulation pipe 200c-1 of the water separator 220 is connected to the upper part of the water separator 220 and the outlet heat medium circulation pipe 200c-2 of the water separator 220 is connected to the The water level sensor 221 and the air vent 222 are connected to the lower part of the separator 220. The water level sensor 221 and the air vent 222 are provided on the inlet side heat medium circulation pipe 200c-1.

A hot water supply unit 400 for supplying the hot water of the thermal storage tank 300 to the power reception side 450; And a boiler 500 for supplementarily heating and supplying the hot water of the thermal storage tank 300 when the hot water temperature of the thermal storage tank 300 is lower than a set temperature, A hot water discharge pipe 410 connected to the upper part of the solar water heater 300 and discharging hot water from the thermal storage tank 300 and the hot water discharge pipe 410 branched from the solar hot water discharge pipe 410 and connected to the faucet 450, A first connection pipe 470 branched to the other side of the solar hot water discharge pipe 410 and connected to an inlet of the boiler 500; And a second connection pipe (480) connecting the outlet of the boiler (500) and the hot water supply pipe (420) at a position remote from the outlet of the anisotropic valve (430), and the second connection pipe ) From the outlet of the boiler (500) Group, but the hot water flow in toward the hot water supply pipe (420) direction is permitted, the hot water flows in the opposite direction may be provided with a check valve 490 to block.

The controller 600 includes a temperature sensor 310 for detecting the temperature of the hot water stored in the upper portion of the thermal storage tank 300, When the detected temperature is equal to or higher than the set temperature, the anisotropic valve 430 is opened, and when the temperature detected by the accumulator over-temperature sensor 310 is lower than the set temperature, the anisotropic valve 430 is closed And controlling the boiler 500 to be ignited.

According to the solar hot water system of the present invention, the water heater separator having the function of detecting the water level of the heating medium is provided on the inlet side of the heat collecting circulation pump, and the pressurizing operation, in which the operation is controlled so that the heating medium stored in the heat- By providing the pump and the check valve at the outlet side of the pump, stable collection of solar heat can be achieved through stable operation of the heat collecting circulation pump and smooth circulation of the heat medium, and the heat medium is smoothly supplied to the heat collecting circulation pump, Therefore, even when the operation of the pressurizing pump is stopped, the check valve prevents the heat medium from flowing back to the heat medium tank, so that the circulation of the heat medium can be smoothly performed.

A first connection pipe which is branched to one side of the solar hot water discharge pipe and which is connected to the water outlet and which is branched on the other side of the solar hot water discharge pipe so as to be connected to the inlet of the boiler; The second connection pipe is connected between the hot water supply pipes at the position remote from the outlet of the anisotropic valve so that a part of the flow rate of the hot water is circulated through the first connection pipe and the boiler and the second connection pipe, It is possible to supply stable hot water by maintaining the hot water supply temperature uniformly when switching to the boiler hot water supply during the solar hot water supply.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a conventional solar hot water system,
FIG. 2 is a configuration diagram of a solar hot water system according to the present invention,
3 is a control block diagram of a solar hot water system according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a block diagram of a solar hot water system according to the present invention, and FIG. 3 is a control block diagram of a solar hot water system according to the present invention.

A solar hot water system according to the present invention includes a solar heat collector 100, a heat medium circulation pipe 200 connecting the outlet side and the inlet side of the solar collector 100 to constitute a closed circuit through which the heat medium circulates, The hot water of the thermal storage tank 300 is supplied to the water tank 450 side when hot water is used. The hot water is heated by the solar heating water, A boiler 500 for supplementarily heating and supplying the hot water of the thermal storage tank 300 when the temperature of the hot water stored in the thermal storage tank 300 is lower than a temperature suitable for hot water use, And a control unit 600 for controlling the overall operation.

The solar collector 100 collects solar heat and transfers solar heat to a heating medium passing through the inside of the solar collector 100. A collector temperature sensor 110 for sensing the temperature of the heating medium heated by solar heat is provided on the discharge side.

The heat medium circulation pipe 200 includes a heating medium discharge pipe 200a connected to one end of a heat exchange pipe 200b passing through the inside of the heat storage tank 300 at the outlet side of the solar collector 100, And a heating medium return pipe 200c (200c-1,200c-2) connected to the other end of the solar collector 100 and the inlet side of the solar collector 100. [

The heat medium circulation pipe 200 and 200c are provided with a heat collecting circulation pump 210 for feeding the heat medium to be circulated and a water separator 220 located at the inlet side of the heat collecting circulation pump 210. The inlet side heat medium circulation pipe 220c-1 is connected to one side of the upper part of the water separator 220 and the heat medium that has passed through the heat storage tank 300 flows into the upper side of the water separator 220. The other side of the water separator 220 is connected to the outlet side heat medium circulation pipe 220c-2 are connected to discharge the radically heated heat medium.

A water level sensor 221 and an air vent 222 are provided on the upper side of the water separator 220 above the inlet side heat medium circulation pipe 220c-1. The water level sensor 221 senses the level of the heat medium contained in the water separator 220 and senses whether or not the water level is low. The air vent 222 is collected in the upper part of the water separator 220. When the pressure of the air exceeds the set pressure, it is opened by the pressure to discharge the air to the outside.

The heat medium supplement pipe 240 is connected to one side of the heat medium circulation pipe 200a and connected to the heat medium supplement pipe 240. The heat medium supplement pipe 240 is connected to the heat medium supplement pipe 240 through a heat medium circulation And a check valve 260 provided at an outlet side of the pressurizing pump 250 to prevent the heat medium from flowing back to the heat medium tank 230 side.

The heating medium circulation pipe 200 may further include an expansion tank 280 for absorbing the pressure change of the heating medium and a pressure gauge 290 for measuring the pressure inside the heating medium circulation pipe 200.

The level information of the heating medium detected by the water level sensor 221 provided in the water separator 220 is sent to the control unit 600. The control unit 600 determines whether the heating medium is low or not based on the level information of the heating medium, Thereby controlling whether the pump 250 is operated or not. That is, when it is detected by the water level sensor 221 that the level of the heating medium is lower than the set water level, the controller 600 determines that the heating medium is insufficient and transmits an operation signal to the pressure pump 260, Respectively.

When the control unit 600 detects that the heating medium stored in the heating medium tank 230 is supplementarily supplied to the heating medium circulation pipe 220 by the operation of the pressurizing pump 260 and the water level of the heating medium is higher than the set water level by the water level sensor 221, The operation of the pressurizing pump 260 is stopped by transmitting an operation stop signal to the pressurizing pump 260. [ At this time, even if the operation of the pressurizing pump 260 is stopped, the check valve 260 prevents the heat medium from flowing back to the heat medium tank 230.

In the present invention, the water separator 220 having the water level sensing function and the water separating function is provided at the inlet side of the heat collecting circulation pump 210, and the heat medium stored in the heat medium tank 230 at the time of the shortage of the heat medium is supplied to the heat medium circulation pipe The check valve 260 is provided on the outlet side of the pressurizing pump 250 that pressurizes and pressurizes the pressurized fluid to the side of the pressurizing pump 250. The insufficient heat medium can be automatically replenished so that circulation of the heat medium can be smoothly performed, The overload of the circulation pump 210 can be prevented.

The storage tank 300 is provided with a storage tank upper temperature sensor 310 and a storage tank lower temperature sensor 320 for sensing the temperature of the hot water located at the upper and lower portions. The regenerator upper temperature sensor 310 senses the maximum temperature of the hot water stored in the regenerator 300 and the temperature sensor 320 senses the lowest temperature of the hot water stored in the regenerator 300. A direct water supply pipe 330 is connected to the lower part of the thermal storage tank 300. The heat storage tank 300 is provided with an anisotropic valve 340 and a safety valve 350 which are opened and closed to discharge the superheated steam and the hot water so that the pressure of the storage tank 300 is properly maintained. And a drain pipe 360 may be provided at a lower side of the drain pipe 360.

The hot water supply unit 400 includes a solar hot water discharge pipe 410 connected to an upper part of the thermal storage tank 300 and discharging hot water from the thermal storage tank 300 and a hot water discharge pipe 410 branched from the solar hot water discharge pipe 410, A hot water supply pipe 420 connected to the hot water discharge pipe 410 and provided with an anisotropic valve 430 for controlling the flow of hot water and a second connection pipe 420 connected to the inlet of the boiler 500, And a second connection pipe 480 connecting between the outlet of the boiler 500 and the hot water supply pipe 420 at a position remote from the outlet of the anisotropic valve 430.

The second connection pipe 480 is provided with a check valve 490 that permits hot water flow from the outlet of the boiler 500 toward the hot water supply pipe 420 while blocking hot water flow in the opposite direction do.

The bypass pipe 460 branched to the hot water supply pipe 420 is connected to the direct water supply pipe 330 and the mixed flow rate of the hot water and the direct water is controlled in the connection portion between the bypass pipe 460 and the hot water supply pipe 420. And a mixing valve 440 for adjusting the temperature of the hot water discharged through the water receiver 450 to the temperature set by the temperature controller 540.

The boiler 500 is used for heating the hot water flowing through the first connection pipe 470 from the heat storage tank 300 and supplying the heated hot water through the second connection pipe 480 when the solar energy is insufficient, In this case, the heating water supply pipe 510 to which the heated water is supplied to the heating load 530 and the heating water supply pipe 510 to which the heating water is passed through the heating load 530 are used as heat sources, (520) are connected.

The control unit 600 controls the operation of the pressurizing pump 250 to automatically replenish the heating medium and controls the operation of the pressurizing pump 250 so that the temperature measured by the collector temperature sensor 110 and the temperature of the hot water measured by the accumulator bottom sensor 320 When the temperature difference between temperatures is equal to or higher than the set temperature difference, the heat collection circulation pump 210 is controlled to operate.

The control unit 600 compares the measured temperature with the temperature measured by the regenerator over-temperature sensor 310 and controls the opening and closing operations of the anisotropic valve 430 and the ignition operation of the burner provided in the boiler 500. In addition, the control unit 600 controls the opening degree of the mixing valve 440 so that the hot water of the temperature set by the user is supplied from the temperature controller 540.

When the temperature detected by the regenerator over-temperature sensor 310 is equal to or higher than the set temperature, the controller 600 controls the an- other valve 430 to be opened. In this case, the hot water stored in the thermal storage tank 300 is supplied to the power reception side 450 via the solar hot water discharge pipe 410 and the hot water supply pipe 420 as indicated by a solid line arrow in FIG. 2, Some of the hot water stored in the thermal storage tank 300 is supplied to the water supply 450 via the solar hot water discharge pipe 410, the first connection pipe 470, the boiler 500, the second connection pipe 480 and the hot water supply pipe 420, .

When the solar heat energy is sufficient as the heat source for supplying the hot water, the hot water stored in the thermal storage tank 300 is discharged through the solar hot water discharge pipe 410 while the combustion of the boiler 500 is stopped, The hot water of the first connection pipe 470 is connected to the hot water supply pipe 420 via the first connection pipe 470 and the boiler 500 and the second connection pipe 480, And the hot water supplied from the heat storage tank 300 is circulated in the boiler 500 and the second connection pipe 480.

On the other hand, when the temperature detected by the regenerator over-temperature sensor 310 is lower than the set temperature, the control unit 600 controls the an- tora valve 430 to be closed so as to switch from the solar hot water supply to the boiler hot water supply.

In this case, the hot water contained in the thermal storage tank 300 is supplied along the path indicated by the dotted arrow in Fig. That is, the hot water discharged from the heat storage tank 300 flows into the boiler 500 via the solar hot water discharge pipe 410 and the first connection pipe 470, and is heated by heat exchange in the boiler 500, And is supplied to the power receiver 450 via the second connection pipe 480 and the hot water supply pipe 420.

As described above, in the present invention, when the solar heat energy is insufficient for use of hot water, the first connection pipe 470, the boiler 500 and the second connection pipe 480 ) Is filled with the hot water heated at a predetermined temperature, so that the sudden variation of the hot water temperature discharged through the faucet 450 can be minimized, and the hot water supply temperature can be maintained uniformly.

10: Solar collector 11: Collector temperature sensor
20: Heat medium circulation pipe 21: Heat medium circulation pump
22: expansion tank 23: heating medium supplement tank
24: Heat medium replenishment pipe 25: Heat medium replenishment pump
26: discharge pipe 27: safety valve
28: pressure gauge 30: heat exchanger
40: heat storage tank 41: temperature sensor on the storage tank
42: Thermal storage tank bottom temperature sensor 43: Direct water supply pipe
44: Water pipe 50: Hot water circulation pipe
51: hot water circulation pump 60: hot water supply pipe
61: three-way valve 62: faucet
70: boiler 71: first connection pipe
72: second connector 80:
100: solar collector 110: collector temperature sensor
200: Heat medium circulation pipe 210: Collecting circulation pump
220: water separator 221: water level sensor
222: Air vent 230: Heat medium tank
240: heating medium supplement pipe 250: pressure pump
260: Check valve 270:
271: Safety valve 280: Expansion tank
290: Pressure gauge 300: Heat storage tank
310: Temperature sensor at the upper part of the storage tank 320: Temperature sensor at the lower part of the storage tank
330: direct water supply pipe 340:
350: Safety valve 360: Drain pipe
400: hot water supply unit 410: solar hot water discharge pipe
420: hot water supply pipe 430:
440: mixing valve 450: faucet
460: Bypass tube 470: First connector
480: Second connection pipe 490: Check valve
500: boiler 510: heating supply pipe
520: Heat recovery pipe 530: Heating load
540: Temperature controller 600: Control unit

Claims (4)

A solar collector 100 for collecting solar heat and heating the heat medium;
A heat medium circulation pipe 200 connecting the outlet side and the inlet side of the solar collector 100 to constitute a closed circuit through which the heat medium circulates; And
And a heat storage tank (300) having a part of the heat medium circulation pipe (200) through which heat is exchanged between the heating medium heated by the solar heat and hot water stored therein,
The heat medium circulation pipe 200 is provided with a heat collecting circulation pump 210 for feeding and circulating the heat medium in circulation and a water level sensor 221 provided at the inlet side of the heat collecting circulation pump 210 for sensing the level of the heat medium, A water separator 220 including an air vent 222 for separating and discharging the air contained in the water separator 220,
A heat medium supplement pipe 240 is branched at one side of the heat medium circulation pipe 200 and is connected to a heat medium tank 230. A heat medium stored in the heat medium tank 230 is connected to the heat medium supplement pipe 240, And a check valve 260 provided at the outlet side of the pressurizing pump 250 to prevent the heat medium from flowing back to the heat medium tank 230 side,
And a controller (600) for controlling the operation of the pressurization pump (250) when the heating medium low level is sensed based on the level of the heating medium sensed by the water level sensor (221). The method according to claim 1,
The inlet-side heat medium circulation pipe 200c-1 of the water separator 220 is connected to the upper part of the water separator 220,
The heat medium circulation pipe 200c-2 at the outlet of the water separator 220 is connected to the lower portion of the water separator 220,
Wherein the water level sensor (221) and the air vent (222) are provided on the upper side of the inlet-side heat medium circulation pipe (200c-1). The method according to claim 1,
A hot water supply unit 400 for supplying the hot water of the thermal storage tank 300 to the power reception side 450; And
And a boiler (500) for supplementarily heating and supplying hot water of the thermal storage tank (300) when the hot water temperature of the thermal storage tank (300) is lower than a set temperature,
The hot water supply unit (400)
A solar hot water discharge pipe 410 connected to an upper part of the thermal storage tank 300 and discharging hot water from the thermal storage tank 300; A hot water supply pipe 420 provided with an anisotropic valve 430 for interrupting the flow of hot water and a first connection pipe 470 branched from the solar hot water discharge pipe 410 to the other side and connected to the inlet of the boiler 500, And a second connection pipe (480) connecting between the outlet of the boiler (500) and the hot water supply pipe (420) at a point remote from the outlet of the anisotropic valve (430)
The second connecting pipe 480 is provided with a check valve 490 for allowing hot water flow in the direction from the outlet of the boiler 500 toward the hot water supply pipe 420 while blocking hot water flow in the opposite direction, Wherein the solar water heating system comprises: The method of claim 3,
The storage tank 300 is provided with a storage tank upper temperature sensor 310 for detecting the temperature of the hot water stored in the upper portion of the storage tank 300,
The control unit 600 controls the anterior valve 430 to be opened when the temperature detected by the temperature sensor on the storage tank 310 is equal to or higher than the predetermined temperature, And controls the anisotropic valve (430) to close and controls the boiler (500) to ignite when the temperature is less than the predetermined temperature.

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