KR20090001763U - Heat storage device installed heating apparatus using solar heat - Google Patents

Abstract

The present invention relates to a linked high temperature heat storage device using solar heat. Specifically, it relates to a high temperature heat storage heating apparatus using solar heat having a feature of forcibly circulating high temperature water collected in the high temperature heat storage tank to a heating heat storage tank by installing a high temperature heat storage tank on the top of the collector of the present invention.

Solar heat, heating, heat storage method, linked type

Description

HEAT STORAGE DEVICE INSTALLED HEATING APPARATUS USING SOLAR HEAT}

The present invention relates to a heating system using solar heat. Specifically, the present invention relates to a technique used to absorb heat from sunlight to heat or make hot water.

4 is a view schematically showing the configuration of a conventional heating apparatus using solar heat. As shown in FIG. 4, the conventional solar heating system measures a temperature of water located in the blister 4 of the collector 1 or above a predetermined temperature, or the temperature of the water in the heat storage tank 8 and the collector 1. When the temperature difference of the water of the blister 4 of) became more than a predetermined level, the circulation pump 7 was operated, and the hot water from the collector 1 was collected in the heat storage tank 8.

The circulation motor used for the circulation pump 7 should use a special variable circulation motor, not a general circulation motor. The reason why the special variable circulation motor is used is that the amount of water to be circulated or the speed of circulating water varies depending on the temperature difference between the water temperature of the heat storage tank 8 and the water temperature of the blister 4 of the collector 1. That is, when the temperature difference is small, the water is circulated gradually, and when the temperature difference is large, the circulation speed is increased to quickly collect hot water of high temperature in the heat storage tank 8, and the water temperature of the collector 1 is higher than the water temperature of the heat storage tank 8. In the same or lower case, the circulation pump 7 should not be operated. This complex control is necessary so that a general motor cannot be used. Such a special variable circulation motor has a problem that the repair cost is long and the repair time is long in case of failure.

In addition, the volume of water filled in the heat collector 1 and the heat storage tank 8 varies depending on the temperature, and since the heat collector 1 is disposed above the heat storage tank 8, when the volume of water decreases, the blister of the heat collector 1 An air layer is formed in 4), and the heat transfer performance from the collector 1 to the water is greatly degraded.

In addition, the volume of hot water filled in the collector 1 and the heat storage tank 8 expands in the summer due to the high temperature. Since the collector 1 is disposed above the heat storage tank 8, the pressure increase due to the volume expansion of water increases. It acts as a collector 1 as it is, and damage of the collector 1 is feared.

In addition, whenever there is a temperature difference between the water in the blister 4 of the collector 1 and the water stored in the heat storage tank 8, a small amount of hot water is transferred from the heat collector 1 to the heat storage tank 8. The time it takes to transfer to the heat storage tank 8 is long, and therefore, a lot of heat is lost to the surroundings in the course of the moonlighting.

Therefore, the present invention aims to provide a solar heating apparatus that can use a general motor instead of a special variable circulation motor by simplifying a complicated circulation control method of hot water.

In addition, the air layer is formed in the blister of the collector to prevent the heat transfer performance from the collector to the water is greatly reduced.

In addition, it is intended to prevent damage to the collector by preventing the pressure increase due to the volume expansion of water to act as a collector.

In addition, to reduce the time to transfer the hot water to the heat storage tank to minimize the heat loss in the process of heat transfer.

The object of the present invention is a natural circulation circuit and the natural circulation to form a closed circuit of the water pipe to circulate the high temperature heat storage tank and the heating heat storage tank and the heat storage tank and the high temperature heat storage tank formed with a collector and a temperature sensor connected through the circuit of the water pipe The natural circulation open / close valve is branched from the natural circulation circuit at one side of the natural circulation open / close valve installed in the circuit and is connected to the natural circulation circuit at the other side of the natural circulation valve via a heating heat storage tank. And a forced circulation open / close valve and the heat collector and the high temperature heat storage provided on a heating heat storage tank connection circuit for forming a closed circuit of the water pipe between the heating heat storage tank and the heating heat storage tank connection circuit not overlapping with the natural circulation circuit. Steel with a pump, forming a closed circuit of the water pipe to circulate the tank and the heating heat storage tank When the temperature of the recirculating circuit and the water of the high temperature heat storage tank is higher than a predetermined temperature, the forced circulation circuit is operated by driving the pump of the forced circulation circuit while closing the natural circulation opening and closing valve and opening the forced circulation opening and closing valve. Circulating water through the natural circulation circuit in a state in which the natural circulation open / close valve is opened and the forced circulation open / close valve is closed when the temperature of the water in the high temperature heat storage tank is lower than the predetermined temperature. It is achieved by an associated high temperature heat storage heating apparatus using solar heat including a control unit.

In order to achieve the above object, the high temperature heat storage tank is preferably installed at a position higher than the collector.

In addition, circulating the water through the natural circulation circuit is preferably made by the specific gravity difference between the water stored in the high temperature heat storage tank and the water stored in the collector.

In addition, the high temperature heat storage tank is preferably formed with a free space that is not filled with water to allow expansion of the water.

The heating device according to the present invention thus reduces the cost of using a general motor instead of a special variable circulation motor by simplifying the complex circulation control method of hot water, and the time required for repair in case of failure is also short.

In addition, since the high temperature heat storage tank is located above the collector, an air layer is formed in the blister of the collector to prevent the heat transfer performance of the collector from falling.

In addition, since the high temperature heat storage tank is positioned higher than the collector, the expansion of water is accommodated, so that the pressure increase due to the volume expansion of water acts as a collector, thereby preventing the collector from being damaged.

In addition, since the water is forced to circulate from the high temperature heat storage tank to the heating heat storage tank at once, the time for transferring hot water is shortened, thereby minimizing heat loss during the heat transfer process.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the configuration of the associated high-temperature heat storage heating apparatus using solar heat according to a preferred embodiment of the present invention.

1 is a view schematically showing the configuration of a linked high-temperature heat storage device using solar heat according to a first embodiment of the present invention. As shown in FIG. 1, the linked high-temperature heat storage device using solar heat according to the first embodiment of the present invention connects the water collector 1, the high temperature heat storage tank 10, and the heating heat storage tank 30 with water. It includes a water pipe for moving.

The collector 1 includes a solar heat collecting plate 3 that absorbs heat from sunlight and a blister 4 filled with water receiving heat absorbed from the sunlight, and the water is introduced and discharged through the water pipe.

The high temperature heat storage tank 10 is a tank for storing the hot water heated through the heat collector 1 and is installed at a position higher than the heat collector 1. The high temperature heat storage tank 10 is provided with a temperature sensor 6. When the temperature sensor detects a temperature above a certain temperature, it transmits a signal for operating the circulation pump to be described later to the controller 9. The temperature sensor is preferably installed at a position adjacent to the third water pipe 13 or the fourth water pipe 14 to be described later. Although not shown in FIG. 1, the control unit 9 is connected to various on / off valves and circulation pumps to be described later to control the operation of various on / off valves and circulation pumps according to a signal received from a temperature sensor.

Water pipes extending from the collector 1 and transferring water from the collector 1 to the high temperature heat storage tank 10 are branched into two first water pipes 11 and a second water pipe 12 to be connected to the high temperature heat storage tank ( 10) is connected. In order to transfer water from the high temperature heat storage tank 10 to the collector 1, two third water pipes 13 and a fourth water pipe 14 extend from the high temperature heat storage tank 10 in the direction of the heat collecting pipe. The third water pipe 13 and the fourth water pipe 14 are combined to form one water pipe and connected to the collector 1. A circulation pump 17 is installed in the first water pipe 11, and is opened and closed in the first water pipe 11, the second water pipe 12, the third water pipe 13, and the fourth water pipe 14. The valve is installed. Thus, the circuit of the water pipe which circulates water between the collector 1 and the high temperature heat storage tank 10 is called the natural circulation circuit 100. The natural circulation circuit 100 is provided with a natural circulation open / close valve 22 for selectively opening and closing the natural circulation circuit 100.

The heating heat storage tank 30 is a tank storing high temperature water to be supplied to the heating zone, and is located at a lower position than the collector 1, and has a heating hose pipe 32 and a hot water outlet to supply heating water to the heating zone. The hot water heating tube 34 through which hot water supplied is heated passes.

The water pipe branched from the water pipe on the natural circulation circuit 100 on one side of the natural circulation opening / closing valve 22 is connected to the heating heat storage tank 30 to supply water to the heating heat storage tank 30, and heat storage heat storage. The water pipe for discharging water from the tank 30 is connected to the water pipe on the natural circulation circuit 100 located on the other side of the natural circulation opening / closing valve 22. Forced circulation opening and closing valve 37 is installed in the water pipe branched from the water pipe on the natural circulation circuit 100 on one side of the natural circulation opening and closing valve 22 and connected to the heating heat storage tank 30. The closed circuit of the water pipe connecting between the natural circulation opening and closing valve 22 and the heating heat storage tank 30 is called a heating heat storage tank 30 connection circuit.

2 is a view schematically showing the configuration of a linked high-temperature heat storage device using solar heat according to a second embodiment of the present invention. As shown in FIG. 2, the linked type high-temperature heat storage device using solar heat according to the second embodiment of the present invention includes a collector 1, a high temperature heat storage tank 10, and a heating heat storage tank 30. The configuration is the same as that of the first embodiment, and the configuration of the water pipe for connecting them to move the water is different from those of the first embodiment.

The high temperature heat storage tank 10 is installed at a position higher than the collector 1.

In order to transfer water from the collector 1 to the high temperature heat storage tank 10, one water pipe extending from the heat collector 1 is connected to the high temperature heat storage tank 10. One water pipe for transferring water from the high temperature heat storage tank 10 to the collector 1 is connected to the collector 1. The circuit of the water pipe which circulates water between the collector 1 and the high temperature heat storage tank 10 is called the natural circulation circuit 100. The natural circulation circuit 100 is provided with a natural circulation opening and closing valve 122 for selectively opening and closing the natural circulation circuit 100.

The heating heat storage tank 30 is located at a lower position than the collector 1, and a heating hose tube 32 for supplying heating water to a heating zone therein and a hot water heating tube 34 for heating hot water supplied to the hot water outlet. To pass.

The water pipe branched from the water pipe on the natural circulation circuit 100 on one side of the natural circulation opening / closing valve 22 is connected to the heating heat storage tank 30 to supply water to the heating heat storage tank 30, and heat storage heat storage. The water pipe for discharging water from the tank 30 is connected to the water pipe on the natural circulation circuit 100 located on the other side of the natural circulation opening / closing valve 22. Forced circulation open / close valve 137 and circulation pump 117 are branched from the water pipe on the natural circulation circuit 100 on one side of the natural circulation open / close valve 22 and connected to the heating heat storage tank 30. Is installed. The closed circuit of the water pipe connecting between the natural circulation open / close valve 122 and the heating heat storage tank 30 is called a heating heat storage tank connection circuit.

3 is a view schematically showing the configuration of a linked high-temperature heat storage device using solar heat according to a third embodiment of the present invention. As shown in FIG. 3, the linked high temperature heat storage heating apparatus using solar heat according to the third embodiment of the present invention is the same as the second embodiment of the present invention shown in FIG. There is a difference in using a three-way valve 237 instead of the natural circulation open / close valve and the forced circulation open / close valve.

That is, a three-way valve 237 is formed at a portion where the water pipe is branched to the heating heat storage tank 30 to supply water from the water pipe on the natural circulation circuit 100 to the heating heat storage tank 30. Therefore, when the three-way valve opens the water pipe directly connected to the collector 1 from the high temperature heat storage tank 10 and closes the passage of the water pipe connected to the heating heat storage tank 30, the heat collector 1 and the high temperature heat storage tank 10 are closed. Only between the natural circulation circuit 100 is circulated in the water. When the three-way valve opens the passage of the water pipe connected to the heating heat storage tank 30 and closes the water pipe directly connected to the collector 1 from the high temperature heat storage tank 10, the circulation pump 117 operates, Is circulated through the forced circulation circuit circulated through both the collector 1, the high temperature heat storage tank 10 and the heating heat storage tank (30).

Hereinafter will be described the operation of the linked high-temperature heat storage device using solar heat according to the first embodiment of the present invention.

When the temperature of the high temperature heat storage tank 10 is lower than a predetermined temperature, the opening / closing valve of each of the first water pipe 11 and the third water pipe 13 connected to the high temperature heat storage tank 10 is closed and the second water pipe 12 is closed. The open / close valve of each of the 4th and 4th water pipes 14 is opened. And the natural circulation open / close valve 22 is opened and the forced circulation open / close valve 37 is closed. The set temperature which is a reference for the natural circulation or forced circulation of the water from the high temperature heat storage tank 10 can be selected by the user in the range of 55 degrees Celsius to 75 degrees Celsius suitable as the temperature of the heating water, for example.

In this state, water flows only through the natural circulation circuit 100. Water movement is not a forced circulation but a natural circulation by the specific gravity of the water. Specifically, since the water heated in the collector 1 has the highest temperature among the water on the natural circulation circuit 100, the specific gravity is the smallest and the heated water having the small specific gravity is higher than the collector 1. Go to). When the water heated in the high temperature heat storage tank 10 is discharged from the high temperature heat storage tank 10, the same amount of water is moved to the collector 1. The water heated in the collector 1 in this manner continuously moves to the high temperature heat storage tank 10 to raise the temperature of the water stored in the high temperature heat storage tank 10.

When the temperature of the water stored in the high temperature heat storage tank 10 is above a certain temperature, the temperature sensor transmits a signal to the controller, and the controller closes the natural circulation open / close valve 22 and opens the forced circulation open / close valve 37. The opening and closing valves of the first water pipe 11 and the third water pipe 13 are opened, and the opening and closing valves of the second water pipe 12 and the fourth water pipe 14 are closed to operate the circulation pump.

In this state, the water moves only through the forced circulation circuit. Water movement at this time is forced circulation by a circulation pump. Specifically, as the circulation pump installed in the first water pipe 11 operates, the hot water stored in the high temperature heat storage tank 10 passes through the forced circulation open / close valve 37 opened and flows into the heating heat storage tank 30. . When hot water is supplied from the high temperature heat storage tank 10 to the heating heat storage tank 30 through a forced circulation circuit, after a predetermined time, the temperature of the water stored in the high temperature heat storage tank 10 falls, The temperature sensor sends a signal to the control unit, the control unit stops the circulation pump, closes the forced circulation opening and closing valve 37, opens the natural circulation opening and closing valve 22, the first water pipe 11 and the third water Each on / off valve of the pipe 13 is closed and each on / off valve of the second water pipe 12 and the fourth water pipe 14 is opened. In this state, the water is naturally circulated through the natural circulation circuit 100, and the temperature of the water stored in the high temperature heat storage tank 10 is increased again.

The heating apparatus according to the present invention moves the hot water to the heating heat storage tank 30 by forced circulation only when the temperature of the water stored in the high temperature heat storage tank 10 is above a predetermined temperature, thereby regenerating hot water at a time. As it transfers to the tank, it takes a short time to transfer and therefore less heat is lost to the surroundings during the hot water movement.

At night, there is no sun and the temperature of the collector 1 is cooled so that the temperature of the water located in the collector 1 is lower than the temperature of the water stored in the high temperature heat storage tank 10. That is, the specific gravity of the water of the collector 1 becomes larger than the specific gravity of the water stored in the high temperature heat storage tank 10. At this time, since the high temperature heat storage tank 10 is located higher than the collector 1, natural circulation does not occur, and thus the hot water stored in the high temperature heat storage tank 10 may maintain a high temperature.

In the linked high temperature heat storage device according to the present invention, even if the volume of the water filled in the heat collector 1 and the heat storage tank is reduced, since the high temperature heat storage tank 10 is located higher than the heat collector 1, the blister 4 of the heat collector 1 The air layer is prevented from being formed, so that the heat transfer performance of the collector 1 is not lowered. That is, the air layer is generated only in the high temperature heat storage tank 10.

When the volume of hot water filled in the collector 1 and the heat storage tank expands due to the high temperature in the summer, the high temperature heat storage tank 10, which may have an additional space to be filled with water, is higher than the heat collector 1. Since it is arrange | positioned, even when the volume of water expands, the pressure increase by the volume expansion of water can be prevented from acting as the collector 1 as it is.

The heat transfer from the heating heat storage tank 30 to the heating area may be made by directly supplying the water stored in the heating heat storage tank 30 to the heating hose, while the heating hose passes through the inside of the heating heat storage tank 30, and the heating heat storage tank ( The water inside the heating hose may be transferred from the water stored in 30).

In the embodiments of the present invention in the case of forced circulation to transfer the high temperature water from the high temperature heat storage tank 10 to the heating heat storage tank 30, the collector 1, the high temperature heat storage tank 10 and the heating heat storage tank 30 The high temperature water is circulated through all, but the present invention is not limited thereto, and the natural circulation circuit 100 is configured in the same manner as the embodiments of the present invention, but the forced circulation circuit includes the high temperature heat storage tank 10. It is also possible to adopt a configuration in which hot water is circulated only between the high temperature heat storage tank 10 and the heating heat storage tank 30 during forced circulation by allowing the water pipes branched from both sides to be connected through the heating heat storage circuit.

1 is a view schematically showing the configuration of a linked high-temperature heat storage device using solar heat according to a first embodiment of the present invention,

2 is a view schematically showing the configuration of a linked high-temperature heat storage device using solar heat according to a second embodiment of the present invention,

3 is a view schematically showing the configuration of a linked high-temperature heat storage device using solar heat according to a third embodiment of the present invention,

4 is a view schematically showing the configuration of a conventional heating apparatus using solar heat.

Explanation of the Main References

1: collector

10: high temperature heat storage tank

20: heating storage tank

100: natural circulation circuit

200: forced circulation circuit

Claims (4)

A high temperature heat storage tank and a heating heat storage tank having a collector and a temperature sensor connected through a circuit of the water pipe; A natural circulation circuit for forming a closed circuit of the water pipe to circulate the collector and the high temperature heat storage tank; A natural circulation open / close valve installed in the natural circulation circuit; A water pipe is branched from the natural circulation circuit at one side of the natural circulation opening / closing valve and connected to the natural circulation circuit at the other side of the natural circulation valve via a heating heat storage tank, thereby connecting the natural circulation opening / closing valve and the heating heat storage tank. Heating regenerative tank connection circuit forming a closed circuit of the; A forced circulation open / close valve provided on the heating heat storage tank connection circuit which does not overlap with the natural circulation circuit; A forced circulation circuit including a pump and a closed circuit of a water pipe to circulate the collector, the high temperature heat storage tank, and the heating heat storage tank; When the temperature of the water of the high temperature heat storage tank is above a certain temperature, the pump of the forced circulation circuit is driven by closing the natural circulation opening and closing valve and opening the forced circulation opening and closing valve to circulate the water through the forced circulation circuit. And a controller configured to circulate the water through the natural circulation circuit when the natural circulation open / close valve is opened and the forced circulation open / close valve is closed when the temperature of the water in the high temperature heat storage tank is lower than the predetermined temperature. Connected high temperature heat storage device using solar heat. The method of claim 1, The high temperature heat storage tank is linked high temperature heat storage device using solar heat, characterized in that installed in a position higher than the collector. The method of claim 2, The circulating water through the natural circulation circuit is linked to the high temperature heat storage heating apparatus using solar heat, characterized in that made by the specific gravity difference between the water stored in the high temperature heat storage tank and the water stored in the collector. The method of claim 2, The high temperature heat storage tank linked solar heat storage device using solar heat, characterized in that the free space is not filled with water to allow the expansion of the water is formed.

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