KR101092496B1 - Apparatus for draining solar energy collcector to prevent overheating - Google Patents

Abstract

A drain apparatus for preventing overheating of a solar collector and a heat accumulator, the present invention comprising: a collector (10) having a temperature sensor (15) in at least a heat medium path on a high temperature side; A heat storage device 20 connected to the heat collector 10 and the hot water heating pipe 25 and having an expansion tank 28; Heat medium return means (30) which is branched between the collector (10) and the heat storage (20) and has a flow path for draining the heat medium to the return tank (32); And a controller 50 that opens the flow path connected to the return tank 32 when it is determined that the collector 10 is overheated.
Accordingly, the present invention has the effect of improving the safety and durability by preventing overheating of the collector in the event of a sudden load change or an electrostatic accident.

Description

Apparatus for draining solar energy collcector to prevent overheating}

The present invention relates to an overheat prevention drain device of a solar collector, and more particularly, to an overheat prevention drain device of a solar collector for improving safety and durability by preventing overheating of the collector in the event of a sudden load change or an electrostatic accident. will be.

In general, the solar system is more developed and economically advantageous than other alternative energy in the use of heating and heating and hot water supply in houses. It is actively promoted. However, like other alternative energy sources such as wind and geothermal, the development of technology to improve safety and utilization in addition to economic feasibility is expected to be an important factor in expanding market share.

For example, according to the "Failure Diagnosis System of Solar System" of Korean Registered Utility Model Publication No. 0387031, a flow meter which is provided in the piping of the heat collecting section and measures the flow rate of the heat medium passing through the piping, and is provided in the piping of the heat storage section The regenerative flow detection sensor outputs an electric signal according to the flow pressure of the hot water passing through the inside, and the system uses the regenerative flow detection sensor signal, the flow rate measurement value, and the predetermined heat medium setting value when each circulation pump is operated. In the case of abnormal analysis, a configuration including a failure diagnosis controller for lighting a lamp corresponding to the analysis result is proposed.

It promptly alarms the failure of the solar system due to thermal fluid leakage due to the failure of pumps, solar collectors, piping, and various valves, overheating of the collectors, etc. However, the measures to cope with the overheating of the solar collectors are insufficient. Therefore, safety is insufficient.

As another example, according to the "Solar Hot Water Heater" of Korean Registered Utility Model Publication No. 0445815, the hot water heating pipe connected to the hot water storage tank and the hot water storage tank is stored in the heat storage tank by using the hot water heat exchanger. This paper proposes a technology that maximizes the annual operation rate by eliminating the shortage of hot water supply and by heating hot water by using enough heated heating water during the period of no heating.

 It is equipped with an overheat radiator that radiates the overheat amount of the solar collector by operating a radiating circulation pump connected to the solar collector, but when the load is suddenly reduced, the energy balance is broken or when the heat medium of the collector is suddenly overheated. It is difficult to deal quickly.

"Fault diagnosis system of solar thermal system" of Korean Utility Model Publication No. 0387031 "Solar hot water heater" of Korean Registered Utility Model Publication No. 0445815

An object of the present invention for improving the conventional problems as described above, to prevent overheating of the collector in the event of sudden load fluctuations or electrostatic accidents to provide an overheat prevention drain device of the solar collector for improving safety and durability have.

In order to achieve the above object, the present invention provides a drain device for preventing overheating of a solar heat collector and a heat storage device, comprising: a heat collector having a temperature sensor on at least a heat medium path on a high temperature side; A heat storage device connected to the heat collector and the hot water heating pipe, and having an expansion tank; Heat medium return means branched between the heat collector and the heat storage device and having a flow path for draining the heat medium to the return tank; And a controller for opening a flow path connected to the return tank when it is determined that the collector is overheated.

In addition, according to the present invention, the heat accumulator is characterized in that it comprises a cross-flow passage for heat exchange between the heat medium of the collector and the hot water heating water of the hot water heating pipe.

In addition, according to the present invention, the heat medium return means includes a pump and a check valve on a low temperature supply pipe connected to a lower side of the return tank, and a check valve and a safety valve on a high temperature return pipe connected to an upper side of the return tank. It is done.

In addition, according to the present invention, the heat medium return means is characterized in that it further comprises a bypass pipe and the opening and closing valve before and after the pump in the low temperature supply pipe.

On the other hand, the terms or words used in the present specification and claims are not to be construed as limiting the ordinary or dictionary meanings, the inventors should use the concept of the term in order to explain the invention in the best way. It should be interpreted as meanings and concepts corresponding to the technical idea of the present invention based on the principle that it can be properly defined. Therefore, the embodiments described in the present specification and the configuration shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all of the technical ideas of the present invention, and various alternatives may be substituted at the time of the present application. It should be understood that there may be equivalents and variations.

As described above, according to the overheat prevention drain device of the solar collector according to the present invention, it is possible to prevent overheating of the collector in the event of a sudden load change or an electrostatic accident, thereby improving safety and durability.

1 is a block diagram showing the connection state of the main part of the device according to the present invention.

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

Figure 1 is a block diagram showing the connection state of the main part of the apparatus according to the present invention.

The present invention relates to a drain device that prevents overheating of solar collectors and heat accumulators. A flat plate collector having a relatively simple structure is the most prevalent form and is a standard of the present invention, but is not limited thereto. In the case of a flat plate collector, the absorbing surface is a structure in which the copper tube and the copper plate are joined by a roll forming method to improve thermal conductivity. The reference temperature for overheating is set differently according to the type of solar system (collector).

According to the present invention, at least a collector 10 having a temperature sensor 15 in the heat medium flow path on the high temperature side is used. In the collector 10, the low temperature supply pipe 41 and the high temperature supply pipe 43 constitute a heating medium circulation path. The low temperature supply pipe 41 is a flow path through which a liquid heat medium flows in, and the high temperature supply pipe 43 is a flow path through which a gaseous heat medium absorbing solar energy is discharged. The temperature sensor 15 may be installed at the high temperature supply pipe 43 side, but may be additionally installed at the low temperature supply pipe 41 side.

In addition, according to the present invention, the heat storage unit 20 having an expansion tank 28 is connected to the heat collector 10 and the hot water supply heating pipe 25. The heat accumulator 20 is connected to the heat collector 10 through a flow path through which the heat medium is circulated, and is connected to the hot water supply heating pipe 25 through a flow path through which the hot water heating water (circulating water) is circulated. Expansion tank 28 installed adjacent to the upper side of the heat accumulator 20 serves to temporarily absorb the expansion of the pressure during the circulation cycle of hot water supply and heating water.

At this time, the heat storage device 20 of the present invention is provided with a cross-flow path for heat-exchanging the heat medium of the heat collector 10 and the hot water heating and heating water of the hot water heating pipe 25 therein. Since the heat exchanger forming the cross flow path is accommodated in the heat storage 20 to reduce the overall design dimension, it is advantageous to construct a packaged solar system.

In addition, according to the present invention, the heat medium return means 30 having a flow path for draining the heat medium to the return tank 32 is branched between the heat collector 10 and the heat storage 20. The heat medium return means 30 branches the high temperature return pipe 44 from the aforementioned low temperature supply pipe 41 and is connected through the heat storage 20 and the low temperature return pipe 42. In more detail, the low temperature supply pipe 41 is connected to the lower side of the return tank 32 to discharge the heat medium in a low temperature state, and the high temperature return pipe 44 together with the low temperature return pipe 42 on the upper side of the return tank 32. It is connected and inflows the heat medium of low temperature or design state.

At this time, the heat medium return means 30 of the present invention includes a pump 34 and a check valve 36 on the low temperature supply pipe 41, the check valve 36 and the safety valve on the high temperature return pipe 44 38 is provided. The pump 34 sends the heat medium in the return tank 32 to the collector 10 through the low temperature supply pipe 41, and the check valve 36 installed adjacent to the downstream side of the pump 34 prevents the back flow of the heat medium. do. The check valve 36 on the high temperature return pipe 44 prevents the backflow of the heat medium when an abnormal high pressure of the return tank 32 is generated, and the safety valve 38 discharges air by generating air when an abnormal high pressure occurs on the return tank 32. Lower.

On the other hand, the heat medium return means 30 of the present invention further includes a bypass pipe 46 and the opening and closing valve 48 before and after the pump 34 in the low temperature supply pipe (41). The bypass pipe 46 is connected to the upstream side and the downstream side of the pump 34 in the low temperature supply pipe 41, and the manual combined electric (AC and DC) driven on / off valve 48 on the bypass pipe 46 is provided. Install). The bypass pipe 46 is one of the flow paths that guide the high temperature heat medium to the return tank 32 when the collector 10 is overheated.

In addition, according to the present invention includes a controller 50 for opening the flow path connected to the return tank 32 when it is determined that the heat collector 10 is overheated. The controller 50 periodically inputs the value of the temperature sensor 15 of the collector 10 and compares it with the set value. When it is determined that the collector 10 is overheated, the controller 50 opens the on / off valve 48 to heat the medium in the collector 10. Drain The controller 50 may be provided with an auxiliary power source 55 of DC (or AC) power source by a rechargeable battery in addition to a commercial AC power source.

In operation, in the normal use state, the heat medium circulation path through the low temperature supply pipe 41, the collector 10, the high temperature supply pipe 43, the heat storage 20, and the low temperature return pipe 42 is configured to provide the heat collector 10. Since solar energy is sent from the heat storage device 20 to the hot water supply heating pipe 25, there is no problem in the hot water supply and heating.

If an urgent situation such as a decrease in load on the hot water heating pipe 25 side, an abnormality in the pipe line of the collector 10, or a power failure occurs, the on / off valve ( Operation 48) opens the flow path of the bypass pipe 46, so that rapid drainage of the heat medium can be achieved. Of course, it is also possible to operate the shut-off valve 48 manually.

On the other hand, the present invention has been described on the basis of the operation corresponding to the overheating of the heat collector 10, the controller 50 senses the high temperature state (eg 80 ℃) of the heat accumulator 20 to quickly transfer the heat medium to the return tank 32 side It is also possible to add an operation to return.

In any case, safety is ensured because the safety valve 38 operates even if the pressure rises due to excessive thermal energy on the return tank 32.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

10: collector 15: temperature sensor
20: heat storage 25: hot water heating piping
28: expansion tank 30: heat medium return means
32: return tank 34: pump
36: check valve 38: safety valve
41: low temperature supply pipe 42: low temperature return pipe
43: high temperature supply pipe 44: high temperature return pipe
46: bypass pipe 48: on-off valve
50: controller 55: auxiliary power

Claims (4)

Drainage device to prevent overheating of solar collector and heat accumulator:
A collector 10 having a temperature sensor 15 in at least the heat medium flow path on the high temperature side;
A heat storage device 20 connected to the heat collector 10 and the hot water heating pipe 25 and having an expansion tank 28;
Heat medium return means (30) which is branched between the collector (10) and the heat storage (20) and has a flow path for draining the heat medium to the return tank (32); And
And a controller (50) for opening the flow path connected to the return tank (32) if it is determined that the collector (10) is overheated. The method of claim 1,
The heat accumulator (20) is an overheat prevention drain device of the solar heat collector, characterized in that it has a cross-flow path for mutual heat exchange between the heat medium of the heat collector (10) and the hot water heating and heating water of the hot water heating pipe (25). The method of claim 1,
The heat medium return means 30 is provided with a pump 34 and a check valve 36 on the low temperature supply pipe 41 connected to the lower side of the return tank 32, and a high temperature return pipe connected to the upper side of the return tank 32. A check valve (36) and a safety valve (38) provided on the (44), overheat prevention drain device of the solar collector. The method of claim 3,
The heat medium return means 30 is a low temperature supply pipe 41, overheat prevention drain device of the solar heat collector, characterized in that it further comprises a bypass pipe 46 and the opening and closing valve 48 before and after the pump (34).

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