KR101229934B1 - The boiler and the solar heat axial line the connection one heating which will beg and warm water system - Google Patents

Abstract

The present invention relates to a heating and hot water system in which a boiler and a solar heat storage tank are connected to each other, and that the first, second, and third circulation pumps and the boiler of the solar heat collector, the heat storage tank, and the heating water supply unit respectively operate the heating water and hot water to the indoor space. In addition to this, it is possible to efficiently reduce unnecessary energy consumption of the first, second and third circulation pumps of the solar collector, the heat storage tank and the heating water supply unit and the boiler, and furthermore, the hot water circulation pipe of the solar collector In addition, there is an effect that it is possible to more easily prevent the risk of freezing in winter.

Solar collector, heat storage tank, boiler, heating water supply, hot water supply, 3-way valve, control unit

Description

THE BOILER AND THE SOLAR HEAT AXIAL LINE THE CONNECTION ONE HEATING WHICH WILL BEG AND WARM WATER SYSTEM}

The present invention is the solar collector, the heat storage tank and the first, second, and third circulation pump and the boiler of the heating water supply unit can be individually operated to supply the heating water and hot water to the indoor space, and thus the solar collector, heat storage tank and heating water. The first, second, and third circulation pumps of the supply unit and the unnecessary energy consumption of the boiler can be efficiently reduced, and the hot water circulation pipe of the solar collector can be more easily prevented from freezing, especially in winter. The present invention relates to a heating and hot water system in which a boiler and a solar heat storage tank are connected.

In general, the boiler is configured to supply hot water for heating and living by using oil or gas as fuel, but the development of eco-friendly alternative energy and the need for environmentally friendly alternative energy are expanding as the price increase of fossil fuel due to the depletion of reserves and the resulting pollution problem increase. It is true.

Therefore, in recent years, a heat storage tank that stores heat transferred through a solar heat collecting plate and a boiler are connected to a boiler and a solar heat storage tank, which is used to heat heating water with solar energy that is stored or to use an auxiliary heat source for heating the heating water of a boiler. Heating and hot water systems have been proposed.

However, since most of the heating and hot water systems linking the boiler and the solar heat storage tank operate both the solar heat storage tank and the boiler at the same time and supply heating water and hot water to the indoor space, the unnecessary energy consumption of the solar heat storage tank and the boiler is high. There is this.

The present invention was created to solve the above problems, the first, second, third circulation pump and the boiler of the solar collector, the heat storage tank and the heating water supply unit can be individually operated to supply the heating water and hot water to the indoor space. Not only this, the first, second and third circulation pumps of the solar collector, the heat storage tank and the heating water supply unit and the unnecessary energy consumption of the boiler can be efficiently reduced, and the hot water circulation pipe of the solar collector is particularly used in winter. It is an object of the present invention to provide a heating and hot water system in which a boiler and a solar heat storage tank can be more easily prevented from freezing.

The present invention for achieving the above object is to collect the solar heat to heat the hot water stored therein, the hot water circulation pipe circulated the heated hot water, the first circulation pump for circulating by pumping hot water to the hot water circulation pipe and A solar collector having a first temperature sensor for sensing an external temperature around the hot water circulation pipe; The heating water stored inside receives the heat of the hot water circulating in the hot water circulation tube of the solar collector, maintains a constant temperature, and is connected to the hot water circulation tube of the solar collector to heat the heat of the hot water circulating the hot water circulation tube. A first heat exchanger configured to transfer the heating water, a heating water circulation pipe through which the heating water circulates, a second circulation pump for circulating the water by circulating the heating water into the heating water circulation pipe, and a second temperature sensor sensing a temperature of the heating water. A heat storage tank being; A boiler having a heating water circulation pipe connected to the heating water circulation pipe of the heat storage tank; A heating water supply unit connected to the heat storage tank and the heating water circulation pipe of the boiler to circulate and supply heating water to a heating tube installed in the floor of an indoor space, and a third circulation pump configured to pump the heating water of the heat storage tank and the boiler; A direct receiving tube connected to the heating water circulation pipe of the heat storage tank, a direct supply supply pipe connected to the direct receiving container and the boiler and supplying direct water to the direct receiving container and the boiler, and a flow sensor provided in the direct supply supply pipe; A second heat exchanger provided inside the water container and transferring the heat of the heating water circulating through the heating water circulation pipe of the heat storage tank with the water contained in the water container, and converting the water into hot water; and the water container and the boiler. A hot water supply unit configured of a hot water discharge pipe discharging hot water passed through the indoor space; A three-way valve provided in the heating water supply unit and the hot water supply unit and connected to the heating water circulation pipe of the heat storage tank and the boiler and the direct water supply pipe of the hot water supply unit; The first, second and third circulation pumps of the solar collector, the heat storage tank and the heating water supply unit, the boiler and the 3-way according to the output signals of the first and second temperature sensors of the solar collector and the heat storage tank and the flow rate sensor of the hot water supply unit. It provides a heating and hot water system in conjunction with the boiler and the solar heat storage tank comprising a; a control unit having a switching unit for switching the operation of the valve.

Here, the control unit 130 is provided with a hot water circulation pipe setting unit, a heating water setting unit and a hot water setting unit, the switching unit is the setting of the hot water circulation pipe setting unit, heating water setting unit and hot water setting unit and the first According to the output signal of the two temperature sensor and the flow sensor it is preferable to output the control signals of the first, second, third circulation pump and the boiler and the three-way valve to the control unit.

Further, the control unit 130 is further provided with a heat storage tank setting unit, the heat storage tank provided on the upper side of the solar heat collector is provided with a third temperature sensor for sensing the temperature of the hot water stored in the heat storage tank, the switching unit is the heat storage tank It is preferable to output the control signal of the first circulation pump to the controller in accordance with whether the setting unit is set or the output signal of the third temperature sensor.

According to the present invention, the switching unit provided in the control unit includes the first, second and third circulation pumps of the solar collector, the heat storage tank and the heating water supply unit according to the output signals of the first and second temperature sensors of the solar collector and the heat storage tank and the flow rate sensor of the hot water supply unit. Since the operation of the boiler and the three-way valve is switched, the first, second and third circulation pumps of the solar collector, the heat storage tank, and the heating water supply unit and the boiler can operate to supply heating water and hot water to the indoor space. Not only this, the first, second, and third circulation pumps of the solar collector, the heat storage tank, and the heating water supply unit and the boiler can efficiently reduce unnecessary energy consumption. Furthermore, the first circulation pump is configured to provide hot water of the solar collector. Since the hot water is circulated through the circulation pipe, the hot water circulation pipe can be more easily prevented from freezing, especially in winter. There is an effect.

The switching unit may be configured to control the first, second, and third circulation pumps according to whether the hot water circulation pipe setting unit, the heating water setting unit, the hot water setting unit is set, and the output signals of the first and second temperature sensors and the flow sensor. Since the control signals of the boiler and the 3-way valve are output, the first, second, and third circulation pumps of the solar collector, the heat storage tank, and the heating water supply unit and the boiler can be individually operated more easily. .

In addition, since the switching unit outputs a control signal of the first circulation pump to the control unit according to whether the heat storage tank setting unit is set and the output signal of the third heat source, the hot water circulation pipe of the solar collector may be freeze, especially in winter. There is an effect that can be more easily prevented.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

1 is a schematic view showing a heating and hot water system in which a boiler and a solar heat storage tank are connected as an embodiment of the present invention.

As shown in FIG. 1, the heating and hot water system in which the boiler and the solar heat storage tank are connected to each other is a solar heat collector 10, a heat storage tank 30, a boiler 50, a heating water supply unit 70, and a hot water supply unit. 90, the three-way valve 100 and the control unit 130.

First, the solar collector 10 collects solar heat to heat hot water stored therein.

The solar collector 10 may be installed on the roof of a building including a house.

The solar collector 10 may collect solar heat to heat the hot water stored in the heat storage tank 11 horizontally arranged above.

The solar collector 10 has a hot water circulation pipe 110 through which the heated hot water circulates; A first circulation pump 115 for circulating by pumping hot water into the hot water circulation pipe 110; A first temperature sensor (117 of FIG. 2) for detecting the external temperature around the hot water circulation pipe 110 may be provided.

The hot water circulation pipe 110 may be composed of one side and the other side hot water circulation pipe (111, 113) fixed to both sides of the heat storage tank (11).

The first circulation pump 115 may be connected to the other hot water circulation pipe 113.

The heated hot water stored in the heat storage tank 11 by the operation of the first circulation pump 115 is the one side hot water circulation tube 111, the first heat exchanger 31 to be described later, and the other side hot water circulation tube 113. ), The heat storage tank 11 can be repeatedly cycled (see solid line arrow in FIG. 3).

The first temperature sensor 117 may detect an external temperature around the one side hot water circulation pipe 111 at the outer circumference of the one side hot water circulation pipe 111 and output the signal to the controller 130.

Next, the heat storage tank 30 stores the heating water at a predetermined temperature to be circulated and supplied to the floor of an indoor space including a living room, a home room, and the like of the house.

The heat storage tank 30 may be installed in a building including a house.

The heating water stored in the heat storage tank 30 may receive a heat of hot water circulating in the hot water circulation pipe 110 of the solar collector 10 to maintain a constant temperature.

The first heat exchanger 31 connected to the hot water circulation pipe 110 of the solar heat collector 10 to transfer the heat of the hot water circulating through the hot water circulation pipe 110 to the heating water in the heat storage tank 30. May be provided.

The first heat exchanger 31 may be formed of a coil tube.

One end of the hot water circulation pipe 110 and one end of the other side hot water circulation pipe (111, 113) may be connected to both sides of the heat storage tank 11 of the solar collector 10, respectively.

The other end of the one side hot water circulation pipe 111 may be fixed to the upper side of the first heat exchanger 31,

The other end of the other hot water circulation pipe 113 may be connected and fixed to the lower side of the first heat exchanger (31).

The heat storage tank 30 may be provided with a heating water circulation pipe 310, a second circulation pump 330 and a second temperature sensor (350 of FIG. 2).

The heating water circulation pipe 310 of the heat storage tank 30 may include first and second upper heating water circulation pipes 311 and 313 and first and second lower heating water circulation pipes 315 and 317.

One end of the first upper heating water circulation pipe 311 may be connected and fixed to the other upper portion of the heat storage tank (30).

One end of the second upper heating water circulation pipe 313 is bent in the outer circumferential direction of the lower one side of the first upper heating water circulation pipe 311, and the lower one side of the first upper heating water circulation pipe 311. Can be fixed to the outer periphery.

One end of the first lower heating water circulation pipe 315 may be connected and fixed to the other lower portion of the heat storage tank 30.

A lower end of the second lower heating water circulation pipe 317 may be connected and fixed to one outer circumference of the first lower heating water circulation pipe 315.

The second circulation pump 330 may be connected to the second upper heating water circulation pipe 313.

The heating water stored in the heat storage tank 30 by the operation of the second circulation pump 330 is the first upper heating water circulation pipe 311, the second upper heating water circulation pipe 313, and the second lower side. The heating water circulation pipe 315, the first lower heating water circulation pipe 317, and the heat storage tank 30 may be repeatedly circulated. (See the dotted arrow in FIG. 7).

The second temperature sensor 350 may be provided at an outer circumference of the heat storage tank 30 to detect a temperature of the heating water stored in the heat storage tank 30 and output the signal to the controller 130.

Next, the boiler 50 is to supply the heating water of a predetermined temperature to the floor of the indoor space, including the living room, the room of the house.

The boiler 50 may be installed in a building including a house.

The boiler 50 may heat the heating water stored therein under the control of the controller 130.

The boiler 50 may be provided with a heating water circulation pipe 510 connected to the heating water circulation pipe 310 of the heat storage tank 30.

The heating water circulation pipe 510 of the boiler 50 may include a third upper heating water circulation pipe 511 and a third lower heating water circulation pipe 513.

One end of the third upper heating water circulation pipe 511 may be connected to the other end of the first upper heating water circulation pipe 311 of the heat storage tank 30, and the other end may be disposed at an upper portion of the boiler 50. The connection can be fixed.

One end of the third lower heating water circulation pipe 513 may be connected to the other end of the first lower heating water circulation pipe 315 of the heat storage tank 30, and the other end may be lower than one side of the boiler 50. The connection can be fixed.

Next, the heating water supply unit 70 is connected to the heating water circulation pipes 310 and 510 of the heat storage tank 30 and the boiler 50 and installed in a floor of an indoor space of a building including a house. ) To circulate the heating water.

The heating tube 71 may be formed of a coil tube.

The heating water supply unit 70 may include a heating water outlet pipe 710 and a heating water return pipe 730.

An upper end of the heating water outlet pipe 710 may be connected and fixed to an upper side of the heating pipe 71.

The lower end of the heating water outlet pipe 710 is the other end of the first upper heating water circulation pipe 311 of the heat storage tank 30 and one end of the third upper heating water circulation pipe 511 of the boiler 50. It can be connected with.

A third circulation pump is connected to the heating water outlet pipe 710 to the heating water outlet pipe 710 to pump the heating water of the heat storage tank 30 and the boiler 50 to the heating water outlet pipe 710. 711 may be provided.

The upper end of the heating water return pipe 730 is the other end of the first lower heating water circulation pipe 315 of the heat storage tank 30 and one end of the third lower heating water circulation pipe 513 of the boiler 50. It may be connected to, and the lower end of the heating water return pipe 730 may be fixed to the lower side of the heating tube (71).

Next, the hot water supply unit 90 is for supplying hot water to the indoor space of the toilet, bathroom, etc. of the building, including the house.

The hot water supply unit 90 may be composed of a direct receiving container 910, a direct water supply pipe 930, a flow sensor 950, a second heat exchanger 970 and a hot water discharge pipe 990.

The water receiving container 910 may be provided in the other direction of the heat storage tank 30, and the other end of the second upper heating water circulation pipe 313 of the heat storage tank 30 may be connected to one side thereof.

An upper end of the second lower heating water circulation pipe 317 of the heat storage tank 30 may be connected to one lower side of the water receiving tank 910.

The direct water supply pipe 930 may be connected to the direct water container 910 and the boiler 50 to supply direct water to the direct water container 910 and the boiler 50.

The direct water supply pipe 930 may be connected to a direct water supply unit (not shown).

As the direct water supply unit (not shown), it is possible to use a general water supply and drainage, as well as a tank that receives the direct water, and can be configured as a pump for pumping the direct water contained in the tank to the direct water supply pipe 930, etc. Can be.

The direct water supply pipe 930 may include first, second, third, and fourth direct water supply pipes 931, 933, 935, and 937.

The other end of the first direct water supply pipe 931 may be connected to a direct water supply part (not shown).

One end of the second direct supply pipe 933 may be connected to the direct receiving container 910.

The second water supply pipe 933 may supply the water supplied to the first water supply pipe 931 to the water container 910.

One end of the third direct water supply pipe 935 may be bent in the directions of the first and second direct water supply pipes 931 and 933, and the direct water supplied to the first direct water supply pipe 931 may be supplied to the boiler 50. Can be.

The other end of the third direct supply pipe 935 may be connected and fixed to one side central portion of the boiler 50.

The lower end of the fourth direct supply pipe 937 may be connected and fixed to the upper side of the boiler 50.

The flow sensor 950 is provided in the second direct water supply pipe 933 of the direct water supply pipe 930 to be located at a distance adjacent to the direct water container 910 of the direct water supplied into the second direct water supply pipe 931. The amount may be sensed and the signal may be output to the controller 130.

The second heat exchanger 970 may be provided inside the direct receiving container 910.

The second heat exchanger 970 may be formed of a coil tube.

An upper side of the second heat exchanger 970 may be connected to the other end of the second upper heating water circulation pipe 313 of the heat storage tank 30.

The lower side of the second heat exchanger 970 may be connected to the upper end of the second lower heating water circulation pipe 313 of the heat storage tank 30.

The second heat exchanger 970 may transfer the heat of the heating water circulating in the heating water circulation pipe 310 of the heat storage tank 30 to the direct water received in the water receiving container 910 to convert it into hot water.

One end of the hot water discharge pipe 990 may be fixed to the upper portion of the direct receiving container 910 in a state bent in the upper direction of the direct receiving container 910.

An upper end portion of the fourth direct water supply pipe 937 of the direct water supply pipe 930 may be connected and fixed to the outer circumferential edge of the other end of the hot water discharge pipe 990.

The hot water discharge pipe 990 may discharge the hot water via the direct receiving container 910 and the boiler 50 to an indoor space including a toilet and a bathroom of the house.

Next, the 3-way valve 100 is a heating water outlet pipe 710 and the heating water return pipe 730 of the heating water supply unit 70, the first direct water supply pipe 931 of the hot water supply unit 90. It is provided in the heat storage tank 30 and the heating water circulation pipe (310, 510) of the boiler 50 and is connected to the second, third straight water supply pipe (933, 935) of the hot water supply (90).

The three-way valve 100 may be composed of first, second and third three-way valves 101, 103 and 105.

The first three-way valve 101 is provided at the lower end of the heating water outlet pipe 710 of the other end of the first upper heating water circulation pipe 311 of the heat storage tank 30 and the boiler 50. It may be connected to one end of the third upper heating water circulation pipe 511.

The second three-way valve 103 is provided at the upper end of the heating water return pipe 730 and the other end of the first lower heating water circulation pipe 315 of the heat storage tank 30 and the boiler 50. It may be connected to one end of the third lower heating water circulation pipe (513).

The third three-way valve 105 is provided at one end of the first direct water supply pipe 931 to be connected to the other end of the second direct water supply pipe 933 and one end of the third direct water supply pipe 935. Can be.

2 is a block diagram schematically illustrating a control state of the controller 130.

Next, the control unit 130 receives power from the power supply unit 132, the first, second and third circulation pumps 115, 330 of the solar collector 10, the heat storage tank 30 and the heating water supply unit 70. , 711 and to control the boiler 50 and the three-way valve (100).

As shown in FIG. 2, the controller 130 includes first, second and third circulation pumps 115, 330, and 711 of the solar collector 10, the heat storage tank 30, and the heating water supply unit 70, and the boiler ( 50 and a switching unit 131 for switching the operation of the three-way valve 100 may be provided.

The switching unit 131 is the control unit according to the output signals of the first and second temperature sensors 117 and 350 of the solar heat collector 10 and the heat storage tank 30 and the flow rate sensor 950 of the hot water supply unit 90. A control signal of the first, second, and third circulation pumps 115, 330, and 711, the boiler 50, and the three-way valve 100 may be output to 130.

Next, the control unit 130 may be provided with a hot water circulation pipe setting unit 133, a heating water setting unit 135 and a hot water setting unit 137 by a push button or a dial button method.

A user operates the hot water circulation pipe setting unit 133, the heating water setting unit 135, and the hot water setting unit 137, respectively, to the controller 130 to the hot water circulation pipe 110 of the solar collector 10. A reference temperature value (T ₁ , hereinafter referred to as a 'first reference temperature value') of the surrounding outside;

And a reference temperature value (T ₂ , hereinafter referred to as a 'second reference temperature value') of the heating water to be circulated and supplied to the heating tube 71 installed in the floor of an indoor space of a building including a house. ;

The hot water supply unit 90 may set a reference temperature value (T ₃ , hereinafter referred to as 'the third reference temperature value') of hot water to be supplied to an indoor space such as a bathroom or a bathroom of a building including a house.

3 is a configuration diagram schematically illustrating a state in which hot water of the solar collector 10 circulates.

More specifically, first, the user operates the hot water circulation pipe setting unit 133 in the ON state and simultaneously operates the hot water circulation pipe setting unit 133 to give the control unit 130 a first reference temperature value (T). ₁ ) can be set.

In the present invention, it is assumed for convenience of description that the first reference temperature value T ₁ set in the controller 130 is 15 ° C.

The external temperature around the one side hot water circulation pipe 111 sensed by the first temperature sensor 117 provided on the outer periphery of the hot water circulation pipe 111 of the hot water circulation pipe 110 of the solar collector 10 is If the first reference temperature value T ₁ , that is, less than 15 ℃,

The switching unit 131 outputs a control signal of the first circulation pump 115 of the solar collector 10 to the controller 130.

The control unit 130 operates the first circulation pump 115 according to the control signal output from the switching unit 131, so that the hot water of the solar collector 10 is supplied to the hot water circulation tube ( 110 can be cycled (see solid arrow in FIG. 3).

When the external temperature around the one side hot water circulation tube 111 sensed by the first temperature sensor 117 is the first reference temperature value T ₁ , that is, 15 ° C. or more,

The controller 130 stops the operation of the first circulation pump 115 according to the control signal output from the switching unit 131.

According to the external temperature value around the one side hot water circulation pipe 111 sensed by the first temperature sensor 117, the first circulation pump 115 controls the solar heat collector 10 under the control of the controller 130. Since the hot water is circulated, the hot water circulation pipe 110 may be more easily prevented from freezing, particularly in winter.

4 and 5 are diagrams schematically showing a state in which the heating water is circulated.

Next, the user may operate the heating water setting unit 135 in the ON state and at the same time operate the heating water setting unit 135 to set the second reference temperature value T ₂ in the control unit 130. have.

In the present invention, for convenience of description, it is assumed that the second reference temperature value T ₂ set in the controller 130 is 50 ° C.

The temperature of the heating water stored in the heat storage tank 30 sensed by the second temperature sensor 350 provided at the outer circumference of the heat storage tank 30 is the second reference temperature value T ₂ , that is, 50 ° C. If in case

The switching unit 131 is the control unit 130 of the first, second three-way valves (101, 103) and the third circulation pump 711 of the boiler 50 and the heating water supply unit 70 The control signal is output.

The control unit 130 according to the control signal output from the switching unit 131 as shown in Figure 4 the first three-way valve 101 is the third upper side heating water circulation pipe of the boiler 50 ( Control to be connected to one end of the 511.

In addition, the control unit 130 according to the control signal output from the switching unit 131 as shown in Figure 4 the second three-way valve 103 is the third lower heating water circulation of the boiler 50 It is controlled to be connected to one end of the tube (513).

In this state, by the control of the controller 130, the boiler 50 heats the heating water stored therein.

At the same time, the control unit 130 operates the third circulation pump 711 and the high temperature heating water stored in the boiler 50 as shown in FIG. 4 is a heating water circulation pipe 510 of the boiler 50. ) And the heating tube 71 installed in the floor of the interior space of the building including the house (see solid arrow in FIG. 4).

When the temperature of the heating water stored in the heat storage tank 30 sensed by the second temperature sensor 350 is the second reference temperature value T ₂ , that is, 50 ° C. or more,

The switching unit 131 outputs the control signals of the first and second three-way valves 101 and 103 and the third circulation pump 711 of the heating water supply unit 70 to the control unit 130. .

The control unit 130 according to the control signal output from the switching unit 131 as shown in Figure 5 the first three-way valve 101 is the first upper heating water circulation pipe of the heat storage tank ( 311) to be connected to the other end of the control.

In addition, the control unit 130 according to the control signal output from the switching unit 131 as shown in Figure 5 the second three-way valve 103 circulates the first lower heating water of the heat storage tank (30) It is controlled to be connected to the other end of the tube (315).

In this state, the control unit 130 operates the third circulation pump 711 and the heating water of the heat storage tank 30 as shown in FIG. 5 is the first upper heating water circulation pipe 311 of the heat storage tank 30. And the first lower heating water circulation pipe 315 and the heating pipe 71 installed in the floor of the interior space of the building including a house (see a solid arrow of FIG. 5).

6 and 7 are schematic diagrams illustrating a state in which hot water circulates.

Next, the user may operate the hot water setting unit 137 in the ON state and at the same time operate the hot water setting unit 137 to set a third reference temperature value T ₃ in the control unit 130.

In the present invention, for convenience of description, it is assumed that the third reference temperature value T ₃ set in the controller 130 is 30 ° C.

When the temperature of the heating water stored in the heat storage tank 30 sensed by the second temperature sensor 350 of the heat storage tank 30 is less than the third reference temperature value T ₃ , that is, 30 ° C.,

The switching unit 131 outputs a control signal of the third three-way valve 105 and the third circulation pump 711 of the boiler 50 and the heating water supply unit 70 to the control unit 130. do.

The control unit 130 may be connected to the lower end of the third direct supply pipe 935 as shown in Figure 6 in accordance with the control signal output from the switching unit 131. Will be controlled.

Direct water continuously supplied into the first direct water supply pipe 931 flows into the boiler 50 through the third direct water supply pipe 935, and the boiler 50 is controlled by the controller 50. The direct water introduced into the interior is heated to convert it into hot water of high temperature.

Direct water converted to hot water by the boiler 50 may be discharged to the indoor space of the toilet, bathroom, etc. of the house passing through the hot water discharge pipe 990 of the hot water supply unit 90 (solid line arrow of Figure 6). Reference.)

When the temperature of the heating water stored in the heat storage tank 30 sensed by the second temperature sensor 350 of the heat storage tank 30 is the third reference temperature value T ₃ , that is, 30 ° C. or more,

The switching unit 131 outputs a control signal of the third three-way valve 105 to the control unit 130.

In addition, the switching unit 131 outputs a control signal of the second circulation pump 330 to the controller 130 according to the output signal of the flow sensor 950.

According to a control signal output from the switching unit 131, the controller 130 may connect the third three-way valve 105 to the other end of the second straight supply pipe 933 as shown in FIG. 7. Will be controlled.

Direct water continuously supplied into the first direct water supply pipe 931 may be received into the direct water container 910 after passing through the second direct water supply pipe 933.

At this time, the flow rate sensor 950 detects the number of water supplied into the second direct water supply pipe 933 and outputs the signal to the controller 130.

The switching unit 131 outputs a control signal of the second circulation pump 330 to the control unit 130 according to the output signal of the flow sensor 950,

The control unit 130 operates the second circulation pump 330 according to the control signal output from the switching unit 131 so that the heating water stored in the heat storage tank 30 is the first upper heating water circulation pipe ( 311), the second upper heating water circulation pipe 313, the second heat exchanger 970, the second lower heating water circulation pipe 317, the first lower heating water circulation pipe 315, and the heat storage tank 30 in this order. Can be repeatedly cycled (see dotted arrow in FIG. 7).

The second heat exchanger 970 transmits the heat of the heating water of the heat storage tank 30 circulating the heating water circulation pipe 310 of the heat storage tank 30 by the direct water received in the water receiving container 910. Will be converted to hot water.

Direct water converted to hot water of the high temperature by the second heat exchanger 970 may be discharged to the indoor space of the toilet, bathroom, etc. of the house passing through the hot water discharge pipe 990 of the hot water supply unit 90. See solid line arrow.)

As described above, the switching unit 131 sets the hot water circulation pipe setting unit 133, the heating water setting unit 135, and the hot water setting unit 137, and the first and second temperature sensors 117, respectively. The first, second and third circulation pumps 115, 330, and 711, the boiler 50, and the three-way valve 100 to the controller 130 according to an output signal of the 350 and the flow sensor 950. The first, second and third circulation pumps 115, 330, and 711 of the solar collector 10, the heat storage tank 30, and the heating water supply unit 70 and the boiler 50 are further outputted because they output a control signal. There is an advantage that each can be easily operated individually.

Next, a third temperature sensor (119 of FIG. 2) is provided at an outer circumference of the heat storage tank 11 of the solar heat collector 10 to sense the temperature of hot water stored in the heat storage tank 11 of the solar heat collector 10. Can be.

In addition, the control unit 130 may be provided with a heat storage tank setting unit (139 in FIG. 2) by a push button or a dial button method.

The user manipulates the heat storage tank setting unit 139 and refers to the reference temperature value T ₄ of the hot water stored in the heat storage tank 11 of the solar heat collector 10 in the control unit 130. Can be set).

More specifically, the user may operate the heat storage tank setting unit 139 in the ON state and at the same time operate the heat storage tank setting unit 139 to set the fourth reference temperature value T ₄ in the control unit 130. .

In the present invention, for convenience of description, it is assumed that the fourth reference temperature value T ₄ set in the controller 130 is 65 ° C.

The temperature of the hot water stored in the heat storage tank 11 of the solar heat collector 10 detected by the third temperature sensor 119 provided at the outer periphery of the heat storage tank 11 of the solar heat collector 10 is the fourth reference temperature value. (T ₄ ) In other words, less than 65 ℃,

The switching unit 131 outputs a control signal of the first circulation pump 115 of the solar collector 10 to the controller 130.

The control unit 130 operates the first circulation pump 115 according to the control signal output from the switching unit 131, and as shown in FIG. 110 can be cycled (see solid arrow in FIG. 3).

When the temperature of the hot water stored in the heat storage tank 11 of the solar heat collector 10 detected by the third temperature sensor 119 is the fourth reference temperature value T ₄ , that is, 65 ° C. or more,

The controller 130 stops the operation of the first circulation pump 115 according to the control signal output from the switching unit 131.

As described above, the switching unit 131 sets the first circulation pump 115 to the controller 130 according to whether the heat storage tank setting unit 139 is set and the output signal of the third temperature sensor 119. Since the control signal of the output of the hot water circulation pipe 110 of the solar collector 10, in particular, there is an advantage that can be more easily prevent the risk of freezing in winter.

Next, the control unit 130 may be provided with a timer (138 of FIG. 2) by a push button or a dial button method.

A user manipulates the timer 138 to cycle the hot water stored in the heat storage tank 11 of the solar collector 10 to the controller 130 to circulate the hot water circulation pipe 110 of the solar collector 10 or The cycle time interval can be set.

For example, when the cycle time set by the user to the controller 130 through the timer 138 is 1 pm, 3 pm, 4 pm, and 7 pm,

The controller 130 operates the first circulation pump 115 according to a control signal output from the switching unit 131 at 1 pm, 3 pm, 4 pm, and 7 pm.

As another example, when the cycle time interval set by the user through the timer 138 to the controller 130 is 30 minutes,

The control unit operates the first circulation pump 115 according to a control signal output by the switching unit 131 every 30 minutes.

In the present invention configured as described above, the switching unit 131 provided in the controller 130 includes the first and second temperature sensors 117 and 350 and the hot water supply unit of the solar collector 10 and the heat storage tank 30. The first, second and third circulation pumps 115, 330, and 711 of the solar collector 10, the heat storage tank 30, and the heating water supply unit 70 according to the output signal of the flow sensor 950 of 90 and the Since the operation of the boiler 50 and the three-way valve 100 is switched, the first, second, and third circulation pumps 115, 330 of the solar collector 10, the heat storage tank 30, and the heating water supply unit 70 are provided. , 711 and the boiler 50 may be individually operated to supply the heating water and hot water to the indoor space, and as a result, the first of the solar collector 10, the heat storage tank 30, and the heating water supply unit 70. , 2, 3 circulation pumps (115, 330, 711) and there is an advantage that can be efficiently reduced unnecessary energy consumption of the boiler (50).

Furthermore, since the first circulation pump 115 circulates hot water through the hot water circulation pipe 110 of the solar collector 10, the hot water circulation pipe 110 may be freeze, especially in winter. There is also an advantage to avoid.

1 is a schematic view showing a heating and hot water system in which an embodiment of the present invention is linked to a boiler and a solar heat storage tank,

2 is a block diagram schematically illustrating a control state of a controller;

3 is a configuration diagram schematically showing a state in which hot water circulates in the solar collector;

4 and 5 is a schematic view showing a state in which the heating water circulates,

6 and 7 are schematic diagrams illustrating a state in which hot water circulates.

*** Explanation of symbols for main parts of drawing ***

10; Solar collector, 11; Heat Storage Tank,

110; Hot water circulation tube, 111; One side hot water circulation pipe,

113; The other side hot water circulation pipe, 115; First circulation pump,

117; A first temperature sensor, 119; Third temperature sensor,

30; Heat storage tank, 31; First heat exchanger,

310, 510; Heating water circulation pipe, 311; First upper heating water circulation pipe,

313; A second upper heating water circulation pipe, 315; The first lower heating water circulation pipe,

317; A second lower heating water circulation pipe, 330; Second circulation pump,

350; A second temperature sensor, 50; Boiler,

511; A third upper heated water circulation pipe, 513; Third lower heating water circulation pipe,

70; Heating water supply, 71; Heating Tube,

710; Heating water outlet, 711; Third circulation pump,

730; Heating water return pipe, 90; Hot water supply,

910; Water container, 930; Direct Supply Pipe,

931; First direct supply pipe, 933; Second direct supply pipe,

935; Third direct supply pipeline, 937; Fourth direct supply pipe,

950; Flow sensor, 970; Second heat exchanger,

990; Hot water discharge pipe, 100; 3-way valve,

101; A first three-way valve, 103; Second three-way valve,

105; A third three-way valve, 130; Control,

131; Switching section 132; Power Supply,

133; Hot water circulation pipe setting unit, 135; Heating water setting unit,

137; Hot water setting unit, 138; timer,

139; Heat storage tank setting part.

Claims (3)

Collecting solar heat to heat the hot water stored therein, the hot water circulation pipe 110, the heated hot water circulates, the first circulation pump 115 for pumping and circulating the hot water to the hot water circulation pipe 110, and the A solar collector 10 having a first temperature sensor 117 for sensing an external temperature around the hot water circulation pipe 110; The heating water stored therein receives the heat of the hot water circulating in the hot water circulation pipe 110 of the solar collector 10 to maintain a constant temperature, and is connected to the hot water circulation pipe 110 of the solar collector 10 to the The first heat exchanger 31 which transfers the heat of the hot water circulating the hot water circulation pipe 110 to the heating water, the heating water circulation pipe 310 through which the heating water circulates, and the heating water circulation pipe 310. A heat storage tank 30 having a second circulation pump 330 for pumping water and circulating the water, and a second temperature sensor 350 for sensing a temperature of the heating water; A boiler (50) provided with a heating water circulation pipe (510) connected to the heating water circulation pipe (310) of the heat storage tank (30); Connected to the heating water circulation pipes 310 and 510 of the heat storage tank 30 and the boiler 50, the heating water is circulated and supplied to the heating pipe 71 installed in the floor of the indoor space, and the heat storage tank 30 and the boiler ( A heating water supply unit 70 provided with a third circulation pump 711 for pumping heating water of 50; Direct receiving tank 910 connected to the heating water circulation pipe 310 of the heat storage tank 30, the direct receiving container 910 and the boiler 50 is connected to the direct receiving container 910 and the boiler Direct water supply pipe 930 for supplying the direct water to the 50, the flow sensor 950 provided in the direct water supply pipe 930, and is provided in the direct water container 910 to the direct water container 910 A second heat exchanger 970 for transferring heat of the heating water circulating through the heating water circulation pipe 310 of the heat storage tank 30 to the received direct water, and converting it into hot water; and the water receiving container 910 and the boiler ( A hot water supply unit 90 including a hot water discharge pipe 990 for discharging hot water via 50 to an indoor space; It is provided in the heating water supply unit 70 and the hot water supply unit 90 and the heating water circulation pipes 310 and 510 of the heat storage tank 30 and the boiler 50 and the direct water supply pipe 930 of the hot water supply unit 90 and 3-way valve 100 is connected; The solar heat collector 10 and the heat storage tank according to the output signals of the first and second temperature sensors 150 and 350 of the solar heat collector 10 and the heat storage tank 30 and the flow rate sensor 950 of the hot water supply unit 90. 30 and the switching unit 131 for switching the operation of the first, second, third circulation pumps 115, 330, 711 of the heating water supply unit 70 and the boiler 50 and the three-way valve 100. It is made, including; the control unit 130 is provided, The control unit 130 is provided with a hot water circulation pipe setting unit 133, heating water setting unit 135 and hot water setting unit 137, The switching unit 131 is the setting of the hot water circulation pipe setting unit 133, the heating water setting unit 135 and the hot water setting unit 137 and the first and second temperature sensors (150, 350) and the flow rate According to the output signal of the sensor 950, the control unit 130 controls the first, second and third circulation pumps 115, 330 and 711 and the control signals of the boiler 50 and the three-way valve 100. Output, The control unit 130 is further provided with a heat storage tank setting unit 139, The heat storage tank 11 provided above the solar heat collector 10 is provided with a third temperature sensor 119 for detecting the temperature of the hot water stored in the heat storage tank 11. The switching unit 131 outputs a control signal of the first circulation pump 115 to the controller 130 according to whether the heat storage tank setting unit 139 is set and the output signal of the third temperature sensor 119. and, The heating water circulation pipe 310 provided in the heat storage tank 30 includes a first upper heating water circulation pipe 311 having one end fixed to the other upper portion of the heat storage tank 30; A second upper heating water circulation pipe 313 having one end fixed to the first upper heating water circulation pipe 311; A first lower heating water circulation pipe 315 having one end fixed to the other lower portion of the heat storage tank 30; And a second lower heating water circulation pipe 317 having a lower end connected to the first lower heating water circulation pipe 315. The heating water circulation pipe 510 provided in the boiler 50 has one end connected to the other end of the first upper heating water circulation pipe 311 provided in the heat storage tank 30, and the boiler 50 A third upper heating water circulation pipe 511 to which the other end is connected and fixed to an upper portion of one side; A third lower heating water circulation pipe having one end connected to the other end of the first lower heating water circulation pipe 315 provided in the heat storage tank 30 and having the other end connected to the lower end of one side of the boiler 50. 513, The heating water supply unit 70 is connected to the upper end of the heating tube 71 is fixed to the upper end, the other end of the first upper heating water circulation pipe 311 is provided in the heat storage tank 30 and the boiler. A heating water outlet pipe 710 connected to one end of the third upper heating water circulation pipe 511 provided at the 50; An upper end is connected to the other end of the first lower heating water circulation pipe 315 provided in the heat storage tank 30 and one end of the third lower heating water circulation pipe 513 provided in the boiler 50. A lower end portion of the heating water return pipe 730 connected to the lower side of the heating tube 71; The direct water supply pipe 930 of the hot water supply unit 90 may include a first direct water supply pipe 931 having the other end connected to the direct water supply unit; A second straight water supply pipe 933 having one end connected to the straight water container 910; A third direct water supply pipe 935 having the other end connected and fixed to one side of the boiler 50; A fourth direct water supply pipe 937 having a lower end connected to an upper side of the boiler 50; The three-way valve 100 is provided at the lower end of the heating water outlet pipe 710 and the other end of the first upper heating water circulation pipe 311 provided in the heat storage tank 30 and the boiler 50. A first three-way valve (101) connected to one end of the third upper side heating water circulation pipe (511); The third lower heating water provided at the other end of the first lower heating water circulation pipe 315 provided in the heat storage tank 30 and provided at the upper end of the heating water return pipe 730 and the boiler 50. A second three-way valve 103 connected to one end of the circulation pipe 513; A third three-way valve 105 provided at one end of the first direct water supply pipe 931 and connected to the other end of the second direct water supply pipe 933 and one end of the third direct water supply pipe 935; Made up of A timer 138 is provided for setting a circulation time or a circulation time interval for the hot water stored in the heat storage tank 11 of the solar collector 10 to circulate the hot water circulation pipe 110 of the solar collector 10. Heating and hot water system in conjunction with a boiler and solar heat storage tank. delete delete

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