KR20120137733A - Warm air circulation apparatus saving solar energy - Google Patents

Abstract

PURPOSE: An apparatus for supplying hot air and heating water using solar storage heat is provided to easily supply hot air or heating water by a heat storage unit even in the nighttime. CONSTITUTION: A hot air supply apparatus using solar storage heat comprises a frame(10), a heat storage unit(20), a guide unit(30), a supply unit, and a control unit. The heat storage unit is formed at the front side of the frame, and stores solar heat. The guide unit guides the air to be heat-exchanged with the stored solar heat. The guide unit guides the stored solar heat and heat exchanged air to a room. The supply unit sucks the air into the guide unit. The control unit controls the supply unit.

Description

Warm air and heating device using solar heat storage {WARM AIR CIRCULATION APPARATUS SAVING SOLAR ENERGY}

The present invention relates to a warm air and heating apparatus using solar heat storage that can more easily supply the warm air or heating water to the room during the day as well as at night, especially through the heat storage heat storage heat.

In general, boilers are configured to supply hot water for heating and living by using oil or gas as fuel, but as the price increase of fossil fuel due to the depletion of reserves and the pollution problem increase, the development and necessity of environment-friendly alternative energy is expanded. There is a situation.

Accordingly, in recent years, a technology for supplying warm air and heating water to an indoor space through a solar collector has been proposed, but in this case, it is not possible to supply hot air and heating water at night because it cannot collect solar heat at night. There is a problem.

The present invention was created to solve the above-mentioned problems, the warm air and heating apparatus using solar heat storage that can more easily supply warm air or heating water to the room during the day as well as at night, especially through the heat storage heat storage heat To provide that purpose.

The present invention for achieving the above object is a frame; A heat storage unit provided at the front side of the frame and configured to store solar heat; A guide unit which introduces air to be heat-exchanged with the solar heat accumulated in the heat storage unit to the inside, and guides air in heat-exchanged state with the heat generated by the heat storage unit; A supply unit for sucking and supplying air into the guide unit; It provides a warm air device using a solar heat storage, characterized in that it comprises a control unit for controlling the supply.

Here, the front side of the frame is provided with an accommodating portion accommodated therein, the accommodating portion and the bottom plate; An upper plate and a lower plate respectively formed on upper and lower portions of the bottom plate; One side plate and the other side plate respectively formed at one end and the other end of the bottom plate; a reflection plate for reflecting solar heat to the heat storage unit is provided in the accommodating unit, and heat absorbing solar heat in the reflection plate. It is preferable that an absorbing layer is formed.

In addition, the heat storage unit is preferably made of a pipe member having a heat storage material therein.

Further, the guide portion is preferably made of a coil tube wound spirally on the outer peripheral surface of the heat storage portion.

In addition, the opening and closing valve for opening and closing the guide portion; And a temperature measuring unit configured to measure the temperature of the air guided by the guide unit to the room. The control unit compares the temperature measurement value of the temperature measuring unit with a reference temperature value input to the control unit, and controls the supply unit and the open / close valve. It is desirable to control.

In addition, it is preferable that the inclination angle adjusting unit for adjusting the inclination angle of the accommodating portion, the accommodating portion on the front side of the frame.

And, provided on the upper portion of the solar heat collecting unit for collecting the solar heat to convert into electrical energy; It is preferable that a storage battery is provided to store electrical energy converted by the solar heat collecting unit.

On the other hand, the present invention and the frame; A heat storage unit provided at the front side of the frame and configured to store solar heat; A guide unit for introducing heating water to be heat-exchanged with the solar heat accumulated in the heat storage unit to the inside, and guiding the heating water in a state of heat-exchanging heat with the heat stored by the heat storage unit; A supply unit for supplying heating water into the guide unit; It also provides a heating device using a solar heat storage, characterized in that it comprises a control unit for controlling the supply.

Here, the front side of the frame is provided with an accommodating portion accommodated therein, the accommodating portion and the bottom plate; An upper plate and a lower plate respectively formed on upper and lower portions of the bottom plate; One side plate and the other side plate respectively formed at one end and the other end of the bottom plate; a reflection plate for reflecting solar heat to the heat storage unit is provided in the accommodating unit, and heat absorbing solar heat in the reflection plate. It is preferable that an absorbing layer is provided.

In addition, the heat storage unit is preferably made of a pipe member having a heat storage material therein.

Further, the guide portion is preferably made of a coil tube wound spirally on the outer peripheral surface of the heat storage portion.

In addition, the opening and closing valve for opening and closing the guide portion; A temperature measuring unit is provided to measure the temperature of the heating water guided by the guide unit to the room, and the control unit controls the supply unit and the open / close valve by comparing the temperature measurement value of the temperature measuring unit with a reference temperature value input to the control unit. It is desirable to.

In addition, it is preferable that the inclination angle adjusting unit for adjusting the inclination angle of the accommodating portion, the accommodating portion on the front side of the frame.

And, provided on the upper portion of the solar heat collecting unit for collecting the solar heat to convert into electrical energy; It is preferable that a solar cell is configured to store electrical energy converted by the solar heat collecting unit.

On the other hand, the present invention and the frame; A heat storage unit provided inside the frame and configured to store solar heat; A guide unit for introducing air or heating water to be heat-exchanged with the solar heat stored in the heat storage unit, and guiding air or heating water in a state of heat-exchanging heat with the heat stored by the heat storage unit; A supply unit for supplying air and heating water into the guide unit; It also provides a warm air and heating apparatus using solar heat storage characterized in that it comprises a control unit for controlling the supply unit.

Here, the front side of the frame is provided with an accommodating portion accommodated therein, the accommodating portion and the bottom plate; An upper plate and a lower plate respectively formed on upper and lower portions of the bottom plate; One side plate and the other side plate respectively formed at one end and the other end of the bottom plate; a reflection plate for reflecting solar heat to the heat storage unit is provided in the accommodating unit, and heat absorbing solar heat in the reflection plate. It is preferable that an absorbing layer is formed.

In addition, the heat storage unit is preferably made of a pipe member having a heat storage material therein.

Further, the guide portion is preferably made of a coil tube wound spirally on the outer peripheral surface of the heat storage portion.

In addition, the opening and closing valve for opening and closing the guide portion; A temperature measuring unit measuring a temperature of air or heating water guided by the guide unit to the room; A heating water supply line connected to the guide unit to supply heating water to communicate with the guide unit; A three-way valve provided in the guide unit to connect the guide unit and the heating water supply line; the control unit compares a temperature measurement value of the temperature measuring unit with a reference temperature value input to the control unit; Preferably, the on-off valve and the three-way valve are controlled.

In addition, the hot air mode unit for setting so that the warm air is supplied to the control unit indoors; It is preferable that a mode setting unit consisting of a heating mode unit for setting the heating water can be supplied to the room.

And, the front side of the frame is provided with the inclined portion, the inclination angle adjusting unit for adjusting the inclination angle of the accommodating portion; is preferably provided.

In addition, the solar collector is provided on the upper portion, and collects the solar heat to convert into electrical energy; It is preferable that a solar cell is configured to store electrical energy converted by the solar heat collecting unit.

The present invention has the effect that it is possible to more easily supply the warm air or heating water to the room during the day, in particular at night, through the heat storage unit that the solar heat is stored.

1 is a front view schematically showing a warm air device using the solar heat storage of the present invention,
2 is a side cross-sectional view of FIG. 1,
3 is a cross-sectional view schematically showing a heat storage unit,
4 is a partially enlarged front view schematically illustrating a guide portion spirally wound on an outer circumferential surface of the heat storage portion,
5 and 6 are side cross-sectional views schematically showing an inclination angle control unit,
7 is a schematic view showing a heating apparatus using the solar heat storage of the present invention,
8 is a configuration diagram schematically showing the flow of heating water,
9 is a configuration diagram schematically showing a warm air and a heating device using the solar heat storage of the present invention,
10 is a block diagram schematically illustrating a control state of a controller.
11 is a configuration diagram schematically showing the flow of air according to the warm air mode unit,
12 is a configuration diagram schematically showing a flow of heating water according to a heating mode unit.

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

1 is a front view schematically showing a warm air device using the solar heat storage according to the present invention, Figure 2 is a side cross-sectional view of FIG.

The inventors of the present invention provide a warm air device using solar heat storage, a heating device using solar heat storage (see FIG. 7), and a warm air and heating device using solar heat storage (see FIG. 9), as shown in FIGS. 1 and 2. 10), the heat storage unit 20, the guide unit 30, the supply unit 40, and the control unit (50 of FIG. 10);

First, the frame 10 may be composed of a horizontal frame 110 and a vertical frame 120 of the frame 10.

Each corner of the lower surface of the horizontal frame 110 may be provided with a wheel member 111 including a caster.

The vertical frame 120 may be integrally formed on the upper surface of the rear end of the horizontal frame 110.

Next, the heat storage unit 20 may be provided on the front side of the frame 10.

Solar heat is stored in the heat storage unit 20.

Next, in the case of a warm air device using solar heat storage, the ambient air of the frame 10 to be heat-exchanged with the solar heat stored in the heat storage unit 20 is introduced into the guide unit 30.

In the case of a heating apparatus using solar heat storage, heating water including water to be heat-exchanged with solar heat stored in the heat storage unit 20 is introduced into the guide unit 30.

In the case of a warm air and a heating apparatus using solar heat storage, heating water including ambient air or water of the frame 10 to be heat-exchanged with the solar heat stored in the heat storage unit 20 is introduced into the guide unit 30. do.

The guide unit 30 of the warm air device using solar heat storage guides the air in a state of being heat-exchanged with the solar heat stored by the heat storage unit 20 to the room.

In the case of a heating device using solar heat storage, the guide unit 30 guides the heating water including water in heat exchanged state with solar heat stored in the heat storage unit 20 to the room.

In the case of a warm air and a heating device using solar heat storage, the guide unit 30 guides any one selected from heating water including air or water in a state of being heat-exchanged with solar heat stored in the heat storage unit 20 to the room. .

Next, in the case of a warm air device using solar heat storage, the supply unit 40 sucks the ambient air of the frame 10 and supplies the inside of the guide unit 30.

In addition, in the case of a heating apparatus using solar heat storage, the supply unit 40 supplies heating water including water and the like into the guide unit 30.

In addition, in the case of a warm air and a heating apparatus using solar heat storage, the supply unit 40 supplies any one selected from the heating water including air or water to the inside of the guide unit 30.

The supply unit 40 of the heating device using solar heat storage, the hot air and the supply unit 40 of the heating device using solar heat storage will be described in detail below for convenience of description.

The supply unit 40 of the warm air device using the solar heat storage may be provided on the rear side of the vertical frame 120 of the frame 10 in a state in communication with the guide unit 30.

As the supply part 40 of the warm air device using solar heat storage, the ambient air of the frame 10 is sucked into the guide part 30 and sucked into the guide part 30 and the heat storage part is sucked into the guide part 30. A well-known blower motor 410 or the like capable of discharging high-temperature air that is heat-exchanged with solar heat stored at 20 may be used, but is not necessarily limited thereto.

Next, the control unit 50 may be provided in the frame 10 by controlling the supply unit 40, but is not necessarily limited thereto, and may be provided in various locations. to be.

Next, as shown in FIGS. 1 and 2, an accommodating part 60 may be provided at the front side of the frame 10.

The front side of the receiving portion 60 may be integrally provided with a transparent member (61 of FIG. 2) including a low iron tempered glass.

The receiving part 60 may include a bottom plate 610, an upper plate 620, a lower plate 630, one side plate 640, and the other side plate 650.

The bottom plate 610 may be integrally provided between the front upper part of the horizontal frame 110 of the frame 10 and the front upper part of the vertical frame 120.

The upper plate 620 and the lower plate 630 may be integrally provided on the upper and lower portions of the bottom plate 610, respectively.

The one side plate 640 and the other side plate 650 may be integrally provided at one end and the other end of the bottom plate 610, respectively.

The reflection plate 70 may be provided at a predetermined interval in the up and down direction in the accommodation portion 60.

A heat absorbing plate 62 may be provided inside the accommodating part 60, and the heat absorbing plate 62 may absorb solar heat.

The heat absorption plate 62 may be made of a copper plate or the like.

The heat absorption plate 62 may include an upper heat absorption plate 621 and a lower heat absorption plate 622.

The upper side heat absorption plate 621 may be formed in a lattice shape.

The lower side heat absorption plate 622 may be provided inside the accommodating part 60 to be positioned in a lower direction of the upper side heat absorption plate 621.

The lower heat absorbing plate 622 may be inclined downward in the front direction of the frame 10 as it goes from the upper side to the lower side.

Black chromium or the like may be plated on the outer surface of the heat absorption plate 62 in order to further maximize the solar heat absorption efficiency of the heat absorption plate 62.

The reflective plate 70 may protrude convexly from the transparent member 61 toward the bottom plate 610 while being positioned between the upper heat absorbing plates 621.

The reflector 70 may be made of various materials such as stainless steel and aluminum.

The heat accumulator 20, which is horizontally provided inside the reflector 70, may be provided at a predetermined interval in the up and down direction along the reflector 70.

The reflector 70 reflects solar heat to the heat accumulator 20.

On the outer surface of the reflector 70, a heat absorbing layer (70 in FIG. 1) for absorbing solar heat may be formed at a predetermined interval.

In order to further maximize the solar heat absorption efficiency of the heat absorption layer 71, the heat absorption layer 71 may be made of black chromium, black nickel, an oxide material, and the like.

Heat storage including the air or water introduced into the guide part 30 due to the heat absorbing plate 62, the heat absorbing layer 71, and the reflecting plate 70 and the heat storage unit 20. There is an advantage that the heat exchange efficiency of the solar heat can be improved even more.

On the other hand, although not shown in the drawing, the heat insulating material including a styrofoam, sponge, etc. surrounding the accommodating portion 60 to prevent the heat of the heat stored in the heat storage portion 20 and the air around the frame 10 is It is good to be provided.

3 is a cross-sectional view schematically illustrating the heat storage unit 20.

Next, as shown in FIG. 3, the heat storage unit 20 may be formed of a pipe member 210.

The tube member 210 may be formed of a copper tube having a circular cross section.

The inside of the pipe member 210 may be provided with a known heat storage material 220 that heat storage of solar heat.

In order to further maximize the solar heat storage efficiency of the heat storage unit 20, black chromium or the like may be plated on the outer surface of the pipe member 210 of the heat storage unit 20.

4 is a partially enlarged front view schematically showing the guide portion 30 spirally wound on the outer circumferential surface of the heat storage portion 20.

Next, as shown in FIG. 4, the guide part 30 may be formed of a coil pipe 310 spirally wound around the outer circumferential surface of the pipe member 210 of the heat storage part 20.

The coil tube 310 may be formed of a copper tube having a circular cross section.

The lower portion of the guide portion 30, which may be made of the coil tube 310, the bottom plate 610 in a state penetrating the lower side of the bottom plate 610 of the receiving portion 60 as shown in FIG. It may extend a predetermined length in the rear direction of.

As shown in FIG. 2, the upper part of the guide part 30, which may be made of the coil tube 310, is an upper side of the bottom plate 610 of the accommodating part 60 and the vertical frame 120 of the frame 10. In a state penetrating the upper side of the) in the rear direction of the vertical frame 120 is a predetermined length may be connected to the supply unit 40 in communication.

Since the guide part 30 formed of the coil pipe 310 is wound spirally on the outer circumferential surface of the pipe member 210 of the heat storage part 20, the solar heat and the guide part stored in the heat storage part 20 are formed. Heat exchange time of the heating water including the air or water passing through the interior of the 30 is relatively long, which causes the solar heat accumulated in the heat storage unit 20 and the air passing through the interior of the guide unit 30. Or there is an advantage that the heat exchange efficiency of the heating water, including the water can be improved even more significantly.

Next, as shown in FIG. 2, the on / off valve 80 and the temperature measuring unit 90 may be further provided.

The opening and closing valve 80 may be provided at the upper and lower portions of the guide part 30 to open and close the guide part 30.

The temperature measuring unit 90 is provided on the upper outer circumferential surface of the guide unit 30 to measure the temperature of the heating water including the temperature of the hot air or high temperature water guided by the guide unit 30 to the room. Can be.

In the case of a warm air device using solar heat storage and a heating device using solar heat storage, the control unit 50 compares the temperature measurement value of the temperature measuring unit 90 with a reference temperature value input to the control unit 50 to provide the supply unit. 40 and the on-off valve 80 can be controlled.

In the case of a warm air and a heating apparatus using solar heat storage, the control unit 50 compares the temperature measurement value of the temperature measuring unit 90 with a reference temperature value input to the control unit 50 to supply the 40 and the It is possible to control the on-off valve 80 and the three-way valve 500 to be described later, which will be described in detail below for convenience of description.

Although not shown in the drawing, the controller 50 may be provided with a setting button for setting the temperature of the room or the temperature of the heating water supplied to the room in various ways such as a dial button method or a push button method.

A user may input a reference temperature value to the controller 50 by operating the setting button.

When the temperature measurement value of the temperature measuring unit 90 is less than the reference temperature value input to the control unit 50, the control unit 50 may include heating water including air or water around the frame 10 in the guide unit ( 30 is introduced into the lower side of the heat exchanger and heat-exchanged with the heat stored in the heat accumulating portion 20, and then operating the supply unit 40 to be supplied to the room through the inner upper side of the guide portion 30 and at the same time The on-off valve 80 is controlled to open the guide portion 30.

When the temperature measurement value of the temperature measuring unit 90 is equal to or greater than a reference temperature value input to the control unit 50, the control unit 50 moves air or water around the frame 10 into the guide unit 30. At the same time, the operation of the supply unit 40 is stopped so that the heating water including the water is not introduced, and the opening / closing valve 80 is closed to close the guide unit 30.

5 and 6 are side cross-sectional views schematically showing the inclination angle adjusting unit 100.

Next, the accommodating part 60 may be provided on the front side of the frame 10 to be inclined downward in the front direction of the frame 10 as it goes from the upper side to the lower side.

An inclination angle adjusting unit 100 for adjusting the inclination angle α of the accommodation unit 60 may be provided.

More specifically, as shown in FIGS. 5 and 6, the guide part 30 is located in the guide part 30 so as to be located between the supply part 40 and the open / close valve 80 provided at the upper part of the guide part 30. Corrugated pipe 31 in communication with the 30 may be provided.

The upper rear side of the bottom plate 610 of the accommodation unit 60 may be axially coupled to the front upper side of the vertical frame 120 of the frame 10.

The inclination angle adjusting unit 100 may be formed of a cylinder 101.

The upper side of the cylinder 101 may be axially coupled to the lower rear side of the bottom plate 610 of the receiving portion (60).

The lower side of the cylinder 101 may be axially coupled to the upper front side of the horizontal frame 110 of the frame 10.

Although not shown in the drawing, the controller 50 may be provided with a length adjustment button for adjusting the length of the cylinder 101 in various ways such as a dial button method or a push button method.

The user can adjust the vertical length of the cylinder 101 by operating the length adjustment button, due to which the angle of inclination (α) of the receiving portion 60 can be more easily adjusted according to the sunlight irradiation angle There is an advantage.

Next, the solar collector 200 and the storage battery (300 of FIG. 12) may be provided.

The solar heat collecting unit 200 is provided in the upper direction of the upper plate 620 of the receiving portion 60 in the upper direction toward the lower side toward the front direction of the frame 10 so as to be provided in the upper direction of the frame 10. It may be provided to be inclined downward.

A support 201 for supporting the solar collector 200 in a downwardly inclined state is integrated between the rear upper side of the solar collector 200 and the rear surface of the upper plate 620 of the receiver 60. Can be formed.

Although not shown in the drawing, the storage battery 300 may be provided in more various locations, such as may be provided in the frame 10.

The storage battery 300 may store electrical energy converted by the solar heat collecting unit 200.

The electrical energy stored in the storage battery 300 is supplied to and blocked by the supply unit 40, the open / close valve 80, the cylinder 101, and the three-way valve 500 under the control of the controller 50. Can be.

7 is a configuration diagram schematically showing a heating apparatus using the solar heat storage of the present invention, Figure 8 is a configuration diagram schematically showing the flow of the heating water.

Next, the supply unit 40 of the heating apparatus using solar heat storage may be made of a pump 420 as shown in FIG.

The upper and lower sides of the heating water supply line 400 may be hermetically connected to the upper and lower portions of the guide unit 30 of the heating apparatus using solar heat storage so as to communicate with the guide unit 30, respectively.

Between the rear upper portion and the rear lower portion of the heating water supply line 400 may be hermetically connected to the circulation line 600 installed on the floor of an indoor space such as a home house to communicate with the heating water supply line 400.

The pump 420 and the heat storage tank 402 may be connected to the lower portion of the heating water supply line 400 at a predetermined interval while communicating with the heating water supply line 400.

Inside the heat storage tank 402, the heating water including water and the like may be stored at a predetermined height.

Under the control of the controller 50, the pump 420 is forced to pump the heating water including the water stored at a predetermined height in the heat storage tank 402.

As a result, the heating water including water stored in the heat storage tank 402 is guided through the heating water supply line 400, as shown in FIG. 8, and then the circulation line 600. The heat storage tank 402 is repeatedly moved in the order (see arrow of FIG. 8).

The heating water including water, which flows through the guide part 30 and the circulation line 600 sequentially and flows back into the heat storage tank 402, may be cooled by heat exchange with the heat exchange part of the heat storage tank 402. have.

9 is a configuration diagram schematically showing a warm air and a heating apparatus using the solar heat storage according to the present invention.

Next, the supply unit 40 of the warm air and heating apparatus using solar heat storage may be largely composed of the blower motor 410 and the pump 420 as shown in FIG.

The heating water supply line 400, the circulation line 600, and the heat storage tank 402 may also be provided in a warm air and a heating device using solar heat storage.

In particular, the three-way valve 500 may be provided in the warm air and heating apparatus using solar heat storage.

The three-way valve 500 may be provided in the guide part 30 to connect the guide part 30 and the heating water supply line 400.

The three-way valve 500 may be composed of an upper three-way valve 510 and a lower three-way valve 520.

The upper three-way valve 510 may be provided at the upper part of the guide part 30 to connect the upper part of the front side of the heating water supply line 400 and the upper part of the guide part 30.

In addition, the upper three-way valve 510 may connect the upper portion of the guide unit 30 with the blower motor 410.

The lower three-way valve 520 may be provided under the guide part 30 to connect the lower part of the front side of the heating water supply line 400 and the lower part of the guide part 30.

10 is a block diagram schematically illustrating a control state of the controller 50.

Next, as shown in FIG. 10, the control unit 50 may include a mode setting unit 700.

The mode setting unit 700 may be provided in the controller 50 in various ways such as a dial button method or a push button method.

The mode setting unit 700 includes a warm air mode unit 710 for setting a hot air to be supplied into the room; The heating mode unit 720 may be configured to set the heating water to be supplied to the room.

11 is a configuration diagram schematically illustrating the flow of air according to the warm air mode 710.

When the user sets the warm air mode unit 710 to the ON state, and the heating mode unit 720 to the OFF state,

As shown in FIG. 11, the upper three-way valve 510 connects the upper portion of the guide part 30 to the blower motor 410 by the control of the controller 50.

The lower three-way valve 520 releases the connection between the lower part of the guide part 30 and the lower part of the front side of the heating water supply line 400.

When the temperature measurement value of the air measured by the temperature measuring unit 90 is less than the reference temperature value input to the control unit 50, the control unit 50 is the air around the frame 10 is the guide unit 30 The blower motor 410 of the supply unit 40 to be supplied to the interior of the heat supply unit 40 to be supplied to the room after passing through the inner upper side of the guide unit 30 after being heat-exchanged with the solar heat accumulated in the heat storage unit 20 Simultaneously with operation, the on-off valve 80 is controlled to open the guide part 30.

When the temperature measurement value of the temperature measuring unit 90 is equal to or greater than the reference temperature value input to the control unit 50, the control unit 50 flows air around the frame 10 into the guide unit 30. It stops the blower motor 410 of the supply unit 40 so as not to be able to be controlled at the same time to control the closing valve 80 to close the guide unit (30).

12 is a configuration diagram schematically illustrating the flow of heating water according to the heating mode unit 720.

When the user sets the heating mode unit 720 to the ON state, and the warm air mode unit 710 to the OFF state,

As shown in FIG. 12, the upper three-way valve 510 connects the upper part of the guide part 30 to the upper part of the front side of the heating water supply line 400 by the control of the controller 50.

The lower three-way valve 520 connects the lower part of the guide part 30 and the lower part of the front side of the heating water supply line 400.

When the temperature measurement value of the heating water measured by the temperature measuring unit 90 is less than the reference temperature value input to the controller 50, the controller 50 stores water stored at a predetermined height inside the heat storage tank 402. The heating water including the back flows into the inner lower side of the guide part 30 and exchanges heat with the solar heat accumulated in the heat storage part 20, and then passes through the inner upper side of the guide part 30 to be supplied to the room. The pump 420 of the supply unit 40 is operated and at the same time the on / off valve 80 is controlled to open the guide unit 30.

When the temperature measurement value of the heating water measured by the temperature measuring unit 90 is equal to or greater than the reference temperature value input to the controller 50, the controller 50 stores water stored at a predetermined height inside the heat storage tank 402. It stops the operation of the pump 420 of the supply unit 40 so that the heating water, including the back and the like, and at the same time to control the closing valve 80 to close the guide unit 30.

The present invention configured as described above has an advantage that the hot air and the heating water can be more easily supplied to the room during the day as well as at night through the heat storage unit 20 in which solar heat is accumulated.

10; Frame, 20; Heat Storage Part,
30; Guide, 40; Supply Line,
50; Control section.

Claims (22)

A frame 10;
A heat storage unit 20 provided at the front side of the frame 10 and configured to store solar heat;
Air to be heat-exchanged with the solar heat stored in the heat storage unit 20 is introduced into the inside, and a guide unit 30 for guiding the air in heat-exchanged state with the heat generated by the heat storage unit 20 to the room;
A supply unit 40 for sucking and supplying air into the guide unit 30;
Control unit 50 for controlling the supply unit 40; Hot air device using a solar heat storage, characterized in that comprises a.
The method of claim 1,
An accommodating part 60 is provided at the front side of the frame 10 to accommodate the heat storage part 20 therein,
The receiving part 60 and the bottom plate (610);
An upper plate 620 and a lower plate 630 respectively formed on upper and lower portions of the bottom plate 610;
And configured to include one side plate 640 and the other side plate 650 formed at one end and the other end of the bottom plate 610, respectively.
The reflector 70 is provided inside the receiving portion 60 to reflect the solar heat to the heat storage portion 20,
The warm air device using the solar heat storage, characterized in that the heat absorbing layer 71 is formed on the reflector plate 70 to absorb solar heat.
The method of claim 1,
The heat storage unit 20 is a warm air device using a solar heat storage, characterized in that consisting of a pipe member 210 provided with a heat storage material 220 therein.
The method of claim 1,
The guide unit 30 is a warm air device using a solar heat storage, characterized in that consisting of a coil tube 310 wound spirally on the outer peripheral surface of the heat storage unit (20).
The method of claim 1,
On and off valve 80 for opening and closing the guide portion 30;
Is provided with a temperature measuring unit 90 for measuring the temperature of the air guided by the guide unit 30 to the room,
The control unit 50 controls the supply unit 40 and the open / close valve 80 by comparing the temperature measurement value of the temperature measuring unit 90 with the reference temperature value input to the control unit 50. Warm air device using solar heat storage.
The method of claim 2,
The accommodating part 60 is inclined at the front side of the frame 10,
Warm air device using a solar heat storage, characterized in that provided; inclination angle control unit 100 for adjusting the inclination angle of the receiving portion (60).
The method of claim 1,
A solar heat collector 200 provided on an upper portion of the frame 10 to collect solar heat and convert the solar heat into electric energy;
Warm storage device using a solar heat storage, characterized in that the; is provided with a storage battery 300 that the electrical energy is converted by the solar heat collector 200.
A frame 10;
A heat storage unit 20 provided at the front side of the frame 10 and configured to store solar heat;
A guide unit (30) for introducing heating water to be heat-exchanged with the solar heat stored in the heat storage unit (20), and guiding heating water in a state in which heat is heat-exchanged with the heat stored by the heat storage unit (20);
A supply unit 40 for supplying heating water into the guide unit 30;
And a control unit (50) for controlling the supply unit (40).
The method of claim 8,
An accommodating part 60 is provided at the front side of the frame 10 to accommodate the heat storage part 20 therein,
The receiving part 60 and the bottom plate (610);
An upper plate 620 and a lower plate 630 respectively formed on upper and lower portions of the bottom plate 610;
And configured to include one side plate 640 and the other side plate 650 formed at one end and the other end of the bottom plate 610, respectively.
The reflector 70 is provided inside the receiving portion 60 to reflect the solar heat to the heat storage portion 20,
Heating device using solar heat storage, characterized in that the heat absorbing layer (71) for absorbing solar heat is provided on the reflecting plate (70).
The method of claim 8,
The heat storage unit 20 is a heating device using solar heat storage, characterized in that consisting of a pipe member 210 is provided with a heat storage material 220 therein.
The method of claim 8,
The guide unit 30 is a heating device using solar heat storage, characterized in that consisting of a coil pipe 310 is wound spirally on the outer peripheral surface of the heat storage unit (20).
The method of claim 8,
On and off valve 80 for opening and closing the guide portion 30;
Is provided with a temperature measuring unit 90 for measuring the temperature of the heating water guided by the guide unit 30 to the room,
The control unit 50 controls the supply unit 40 and the open / close valve 80 by comparing the temperature measurement value of the temperature measuring unit 90 with the reference temperature value input to the control unit 50. Heating system using solar heat storage.
The method of claim 9,
The accommodating part 60 is inclined at the front side of the frame 10,
Heating device using solar heat storage, characterized in that provided; inclination angle control unit 100 for adjusting the inclination angle of the receiving portion (60).
The method of claim 9,
A solar heat collector 200 provided on an upper portion of the frame 10 to collect solar heat and convert the solar heat into electric energy;
And a storage battery 300 configured to store electrical energy converted by the solar heat collecting unit 200.
A frame 10;
A heat storage unit 20 provided at the front side of the frame 10 and configured to store solar heat;
Air or heating water to be heat-exchanged with the solar heat stored in the heat storage unit 20 is introduced into the inside, and a guide unit for guiding air or heating water heat-exchanged with the heat generated by the heat storage unit 20 to the room ( 30);
A supply unit 40 supplying air and heating water into the guide unit 30;
Hot air and heating using solar heat storage, characterized in that it comprises a; control unit 50 for controlling the supply unit 40.
16. The method of claim 15,
An accommodating part 60 is provided at the front side of the frame 10 to accommodate the heat storage part 20 therein,
The receiving part 60 and the bottom plate (610);
An upper plate 620 and a lower plate 630 respectively formed on upper and lower portions of the bottom plate 610;
And configured to include one side plate 640 and the other side plate 650 formed at one end and the other end of the bottom plate 610, respectively.
The reflector 70 is provided inside the receiving portion 60 to reflect the solar heat to the heat storage portion 20,
Hot air and heating apparatus using solar heat storage, characterized in that the heat absorbing layer 71 is formed on the reflector plate 70 to absorb solar heat.
16. The method of claim 15,
The heat storage unit 20 is a warm air and heating device using solar heat storage, characterized in that consisting of a pipe member 210 provided with a heat storage material 220 therein.
16. The method of claim 15,
The guide unit 30 is a warm air and heating device using solar heat storage, characterized in that consisting of a coil tube 310 wound spirally on the outer peripheral surface of the heat storage unit (20).
16. The method of claim 15,
On and off valve 80 for opening and closing the guide portion 30;
A temperature measuring unit 90 measuring the temperature of air or heating water guided by the guide unit 30 to the room;
A heating water supply line (400) connected to the guide unit (30) so as to communicate with the guide unit (30) and supplying heating water to the room;
A three-way valve 500 provided at the guide part 30 to connect the guide part 30 to the heating water supply line 400.
The control unit 50 compares the temperature measurement value of the temperature measuring unit 90 with a reference temperature value input to the control unit 50 to provide the supply unit 40, the open / close valve 80, and the three-way valve ( Hot air and heating using solar heat storage, characterized in that for controlling 500).
16. The method of claim 15,
A warm air mode unit 710 for setting warm air to the control unit 50;
Mode setting unit 700 consisting of a heating mode unit 720 for setting the heating water to be supplied to the room; Hot air and heating apparatus using a solar heat storage, characterized in that provided.
17. The method of claim 16,
The accommodating part 60 is inclined at the front side of the frame 10,
Warm air and heating using solar heat storage, characterized in that provided; inclination angle control unit 100 for adjusting the inclination angle of the receiving portion (60).
16. The method of claim 15,
A solar heat collector 200 provided on an upper portion of the frame 10 to collect solar heat and convert the solar heat into electric energy;
Hot air and heating apparatus using a solar heat storage, characterized in that the storage battery; 300 is stored in the electrical energy converted by the solar heat collector 200.

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