KR102562032B1 - Heat block system through sunlight receiving - Google Patents

Abstract

The present invention relates to a heating block system through solar light reception, which is composed of a prefabricated structure by a layered structure of a blowing block part and a heat storage block part, and has excellent on-site constructability, and uses a blowing block part driven by sunlight to blow air. The airflow block unit 100, the heat storage block unit 200, and the air conditioning block unit are forcedly transported to induce smooth air flow, and heat energy from sunlight is effectively exchanged with air by the heat storage block unit to greatly improve the efficiency of generating warm air. (300) as the main configuration.

Description

Heat block system through sunlight receiving}

The present invention relates to a heating block system through solar light reception, and more specifically, it is composed of a prefabricated structure by a layered structure of a blowing block part and a heat storage block part, and has excellent on-site workability and uses a blowing block driven by sunlight. The present invention relates to a heating block system through solar light receiving, which induces smooth air flow by forcibly transporting air and can highly improve warm air generation efficiency by effectively exchanging heat energy of sunlight with air by a heat storage block unit.

Developed countries as well as developing countries around the world present various policies for energy conservation through carbon emission regulation. It provides various benefits and disadvantages.

In the past, the direction of minimizing power consumption was the main direction, but recently, a cooling and heating system that independently produces and consumes energy without an external power supply such as electricity is required.

Accordingly, in the conventionally disclosed Patent Registration No. 10-1998222, a light transmitting plate portion forming a front face facing sunlight and transmitting sunlight to be irradiated; a light-receiving plate part disposed at the rear of the light-transmitting plate part and having a large area facing the light-transmitting plate part or having a large area perpendicular to the light-transmitting plate part to absorb and accumulate thermal energy of sunlight passing through the light-transmitting plate part; a frame forming an outer structure accommodating the light transmitting plate part and the light receiving plate part; a fastening part provided to the light receiving plate part and fixing and attaching the light receiving plate part to the frame; and a heat generating block including a pair of ventilation plates forming the upper and lower surfaces of the heat generating block, forming a plurality of openings, transferring the heat energy to air introduced from the lower part and then flowing upward, and an assembly of the heat generating blocks It forms a block set portion forming part of the outer wall of the building; and a filtering unit disposed under the block set unit to filter outside air of the building and introduce it into the block set unit. a duct having one end provided in the block set unit to provide a conduit through which air heated in the block set unit flows; and a suction unit that is provided at the other end of the duct and randomly draws air heated through the block set unit from the duct to flow into the interior of the building.

However, the prior art naturally heats the air introduced through the heating wall and uses it to maintain an appropriate temperature in the indoor space, but the natural circulation of warm air heated by sunlight is not smooth, so it is difficult to expect a cooling effect. A difficult fate followed.

KR 10-1998222 B1 (2019.07.03.)

Accordingly, the present invention has been conceived to solve the above problems, and is composed of a prefabricated structure by the stacked structure of the blowing block part and the heat storage block part, and has excellent on-site workability, and uses a blowing block part driven by sunlight to blow air. An object of the present invention is to provide a heating block system through solar light reception that induces smooth air flow by forcibly conveying and can highly improve warm air generation efficiency by effectively exchanging heat energy from sunlight with air by a heat storage block unit.

In order to achieve this object, a feature of the present invention is a blowing block unit 100 disposed in an area corresponding to a building wall and provided to output in a filtered state by sucking in outside air; a heat storage block unit 200 that is stacked and arranged in multiple stages above the blowing block unit 100 and is provided to heat filtered air output from the blowing block unit 100 using sunlight; and an air conditioning block unit 300 connected to the uppermost layer of the heat storage block unit 200 and provided to control the indoor temperature using warm air heated by the heat storage block unit 200, wherein the blowing block unit ( 100) and the heat storage block unit 200 are stacked and arranged at a predetermined ratio so that air heated in the heat storage block unit 200 is forcibly transported by the blowing block unit 100.

At this time, the blower block unit 100 is installed in the blower housing 110 having the intake port 112 formed on one side and the exhaust port 114 formed on the upper side, and the air intake port 112 A blower fan 120 that sucks in outside air and outputs it to the exhaust port 114, and a solar panel 130 installed on the outer surface of the blower housing 110 and generating electric energy required to drive the blower fan 120 and a filter member 140 for filtering outside air sucked in by the blowing fan 120 through the intake port, and when the blowing fan 120 is driven by the electrical energy generated by the solar panel 130, It is characterized in that it is provided so that outside air is sucked through the intake port 112 with the blower housing 110 and discharged through the exhaust port 114 in a filtered state through the filter member 140.

In addition, the heat storage block unit 200 is installed inside the heat storage housing 210, in which a transparent window 212 is formed to allow sunlight to pass through the side, and the heat storage housing 210, flowing in through the transparent window 212. The heat storage member 220 that absorbs and accumulates the thermal energy of sunlight, and the heat storage member 220 is penetrated in the longitudinal direction inside the heat storage housing 210 corresponding to the back surface, and the upper and lower exhaust vents of the blower housing 110 ( 113) and a heating passage 230 in which upper and lower air ports 231 and 232 are open, and the heat storage member 220 absorbs thermal energy of sunlight flowing into the transparent window 212, It is characterized in that the air passing through the heating passage 230 is heated by the heat storage of the heat storage member 220 .

In addition, the heat storage member 220 is provided to be reversed by the turning module 400, and the turning module 400 includes a support shaft 410 rotatably supporting the heat storage member 220, and a heat storage member ( 220) It is installed at both ends in the longitudinal direction and connects the eccentric compartment 420 provided as a pair at a position biased in opposite directions to each other in the thickness direction of the heat storage member 220 and the eccentric compartment 420, and both ends are connected to the eccentric compartment (420) The connection pipe 430 extending adjacent to the inner bottom surface, the thermal expansion fluid 440 accommodated inside the eccentric compartment 430, and installed in the longitudinal direction inside the heat storage member 220, the eccentric compartment 430 ) Including a heat insulating material 450 that insulates in one direction, the thermal expansion liquid 440 is accommodated in any one eccentric compartment 420 of the pair of eccentric compartments 420, the thermal expansion liquid 440 is accommodated One end of the heat storage member 220 corresponding to the eccentric compartment 420 is located on the lower side, and one end of the heat storage member 220 corresponding to the empty eccentric compartment 420 is located on the upper side, and the heat storage member 220 ) The eccentric compartment 420 disposed at the bottom is biased toward the side corresponding to the transparent window 212, and the eccentric compartment 420 disposed above the heat storage member 220 is disposed toward the side corresponding to the heating passage 230. When the heat storage member 220 is heated while absorbing the thermal energy of sunlight flowing into the transparent window 212, the thermal expansion fluid 440 is placed in the eccentric compartment 420 located below the heat storage member 220. When the weight of the upper region is increased compared to the lower region of the heat storage member 220 while being heated and moved along the connector 430 by thermal expansion to the side of the eccentric compartment 420 located above the heat storage member 220, the heat storage member 220 is 180 When ° is reversed, one side of the heat storage member 220 heated by sunlight is located in an area corresponding to the heating passage 230 to heat the air, and the other side of the heat storage member 220 corresponds to the transparent window 212. It is characterized in that it is arranged and provided to accumulate thermal energy of sunlight.

In addition, eccentric weights 240 are provided at both ends of the heat storage member 220 so as to be biased in the opposite direction to the eccentric compartment 420, and the heat storage member 220 is tilted at an inclination angle by the eccentric weight 240 It is characterized in that it is provided to face the direction in which sunlight is incident.

In addition, the transparent window 212 is characterized in that formed in a hemispherical shape that matches the rotation radius of the heat storage member 220 and the concentric circle.

In addition, a water supply pipe is connected to pass through the inside of the heat storage member 220, and the water moving along the water supply pipe is heated while passing through the inside of the heat storage member 220, characterized in that it is provided to be used as hot water and heating water. to be

According to the above configuration and operation, the present invention is composed of a prefabricated structure by the stacked structure of the blowing block part and the heat storage block part, so it has excellent on-site constructability, and smooth air flow by forcibly transporting air using the blowing block part driven by sunlight. , and the thermal energy of the sunlight is effectively exchanged with the air by the heat storage block unit, so that the warm air generating efficiency can be highly improved.

1 is a configuration diagram showing a heating block system as a whole through solar light reception according to an embodiment of the present invention.
2 is a configuration diagram showing a state in which a turning module of a heating block system through solar light receiving according to an embodiment of the present invention is applied.
Figure 3 is a configuration diagram showing an enlarged turning module of a heating block system through solar light reception according to an embodiment of the present invention.
4 is a configuration diagram showing an operating state of a turning module of a heating block system through solar light reception according to an embodiment of the present invention.
5 is a configuration diagram showing an eccentric weight of a heating block system through solar light reception according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in the description of the present invention, if it is determined that the related known function may unnecessarily obscure the subject matter of the present invention as an obvious matter to those skilled in the art, the detailed description thereof will be omitted.

1 is a configuration diagram showing a heating block system through solar light reception according to an embodiment of the present invention as a whole, and FIG. 2 is a turning module applied to a heating block system through solar light reception according to an embodiment of the present invention. Figure 3 is a configuration diagram showing a state, and Figure 3 is an enlarged configuration diagram showing the turning module of the heating block system through solar light reception according to an embodiment of the present invention, Figure 4 is a configuration diagram showing the solar light according to an embodiment of the present invention It is a configuration diagram showing an operating state of a turning module of a heating block system through light reception, and FIG. 5 is a configuration diagram showing an eccentric weight of a heating block system through solar light reception according to an embodiment of the present invention.

The present invention relates to a heating block system through solar light reception, which is composed of a prefabricated structure by a layered structure of a blowing block part and a heat storage block part, and has excellent on-site constructability, and uses a blowing block part driven by sunlight to blow air. The airflow block unit 100, the heat storage block unit 200, and the air conditioning block unit are forcedly transported to induce smooth air flow, and heat energy from sunlight is effectively exchanged with air by the heat storage block unit to greatly improve the efficiency of generating warm air. (300) as the main configuration.

The blowing block unit 100 according to the present invention is disposed in an area corresponding to the wall of a building, and is provided to suck in outside air and output it in a filtered state.

The blowing block unit 100 is installed in the blowing housing 110 having the intake port 112 formed on one side and the exhaust port 114 formed on the upper side, and the blowing housing 110 through the intake port 112. A blowing fan 120 that sucks in outside air and outputs it to the exhaust port 114, and a solar panel 130 installed on the outer surface of the blowing housing 110 and generating electric energy required to drive the blowing fan 120, It includes a filter member 140 for filtering outside air sucked in by the blowing fan 120 through the intake port.

Looking at the operating state of the blowing block unit 100, when the blowing fan 120 is driven by the electric energy generated by the solar panel 130, the outside air passes through the air intake port 112 with the blowing housing 110. is provided to be sucked in and discharged through the exhaust port 114 in a filtered state through the filter member 140.

On the other hand, the electrical energy generated by the solar panel 130 is charged in the storage battery and is provided to supply electrical energy without being affected by the presence or absence of sunlight, and is manually or automatically turned on/off by a separate control unit and sensor. It is provided to control operation and air volume.

In addition, the heat storage block unit 200 according to the present invention is stacked in multiple stages on the blowing block unit 100 and is provided to heat the filtered air output from the blowing block unit 100 using sunlight.

At this time, the blowing block unit 100 and the heat storage block unit 200 are stacked and arranged in a predetermined ratio so that the air heated in the heat storage block unit 200 is forcibly transported by the blowing block unit 100. 1 and 2, the blowing block unit 100 shows a state disposed in the lowest layer region corresponding to the building wall, but is not limited thereto, and a configuration in which it is additionally disposed between the heat storage block units 200 is also possible. .

Looking at an embodiment of the heat storage block unit 200 through FIG. 1, it is installed inside the heat storage housing 210 and the heat storage housing 210 in which a transparent window 212 is formed so that sunlight passes through the side, The heat storage member 220 absorbs and accumulates the thermal energy of sunlight introduced through the transparent window 212, and penetrates the inside of the heat storage housing 210 corresponding to the back surface of the heat storage member 220 in the longitudinal direction, and at the top and bottom The upper and lower air ports 231 and 232 communicating with the exhaust port 113 of the blowing housing 110 include a heating passage 230 opened.

The heat storage member 220 absorbs the thermal energy of sunlight flowing into the transparent window 212, and the air passing through the heating passage 230 is heated by the heat storage of the heat storage member 220.

On the other hand, a water supply pipe is connected to pass through the inside of the heat storage member 220, and water moving along the water supply pipe is heated while passing through the inside of the heat storage member 220, and is provided to be used as hot water and heating water. possible.

2 and 3 are configuration diagrams showing another embodiment of the heat storage block unit 200, wherein the heat storage member 220 is provided to be reversed by the turning module 400.

The turning module 400 is installed on a support shaft 410 for rotatably supporting the heat storage member 220 and at both ends of the heat storage member 220 in the longitudinal direction, and in opposite directions in the thickness direction of the heat storage member 220. The eccentric compartment 420 provided as a pair at a biased position and the connecting tube 430 connecting the eccentric compartment 420 and extending so that both ends are adjacent to the inner bottom surface of the eccentric compartment 420, the eccentric compartment 430 ) and a thermal expansion fluid 440 accommodated therein, and a heat insulating material 450 installed in the longitudinal direction inside the heat storage member 220 to insulate the eccentric compartment 430 in one direction.

At this time, both ends of the heat storage member 220 in the longitudinal direction are preferably formed as arcuate curvatures.

The thermal expansion liquid 440 is accommodated in one of the pair of eccentric compartments 420, and one end of the heat storage member 220 corresponding to the eccentric compartment 420 in which the thermal expansion liquid 440 is accommodated. Is located in the lower part, and one end of the heat storage member 220 corresponding to the empty eccentric compartment 420 is located in the upper part.

In addition, the eccentric compartment 420 disposed under the heat storage member 220 is biased toward the side corresponding to the transparent window 212, and the eccentric compartment 420 disposed above the heat storage member 220 serves as a heating flow path. (230) and is disposed biased toward the corresponding side.

Looking at the operating state, when the heat storage member 220 absorbs and heats the thermal energy of sunlight flowing into the transparent window 212 as shown in FIG. 4 (a), in the eccentric compartment 420 located below the heat storage member 220 When the thermal expansion fluid 440 is heated and moved along the connector 430 by thermal expansion to the side of the eccentric compartment 420 located above the heat storage member 220, the weight of the upper region compared to the lower region of the heat storage member 220 increases. When the member 220 is rotated 180°, one side of the heat storage member 220 heated by sunlight is positioned in an area corresponding to the heating passage 230 to heat air, and the other side of the heat storage member 220 is a transparent window. It is disposed correspondingly to 212 and is provided to accumulate thermal energy of sunlight.

In this way, as the heat storage member 220 is turned 180°, one surface of the heat storage member 220 heated by sunlight is exposed to an area corresponding to the heating passage 230 and exchanges heat with the air, thereby increasing the efficiency of generating warm air by heat storage. There are benefits to improving.

In FIG. 5, eccentric weights 240 are provided at both ends of the heat storage member 220 to be biased in the opposite direction to the eccentric compartment 420.

As the heat storage member 220 is tilted at an inclination angle by the eccentric weight 240 and provided to face the direction in which sunlight is incident there is an advantage in that the thermal energy of sunlight can be effectively stored in the heat storage member 220. .

In addition, the transparent window 212 is formed in a hemispherical shape concentric with the radius of rotation of the heat storage member 220 . As a result, the area exposed to sunlight of the heat storage member 220 is not affected by the altitude of the sun, so that heat storage efficiency is improved.

In addition, the air conditioning block unit 300 according to the present invention is connected to the uppermost layer of the heat storage block unit 200 and is provided to control the room temperature using warm air heated by the heat storage block unit 200 .

The air conditioning block unit 300 includes a duct for supplying warm air output through the air passage 210 to a predetermined space, and a damper for controlling air flow through the duct.

As described above, the most preferred embodiment of the present invention has been described in the detailed description of the present invention, but various modifications may be made within a range that does not depart from the technical scope of the present invention. Therefore, the scope of protection of the present invention should not be limited to the above embodiments, but the scope of protection should be recognized from the techniques of the claims to be described later and from these techniques to equivalent technical means.

100: blowing block
200: heat storage block
300: air conditioning block

Claims (7)

a blowing block unit 100 disposed in an area corresponding to a building wall and configured to suck in outside air and output the filtered air; a heat storage block unit 200 that is stacked and arranged in multiple stages above the blowing block unit 100 and is provided to heat filtered air output from the blowing block unit 100 using sunlight; and an air conditioning block unit 300 connected to the uppermost layer of the heat storage block unit 200 and provided to control the room temperature by using the warm air heated by the heat storage block unit 200,
The blowing block unit 100 and the heat storage block unit 200 are stacked and arranged in a predetermined ratio so that air heated in the heat storage block unit 200 is forcibly transported by the blowing block unit 100,
The blowing block unit 100 is installed in the blowing housing 110 having the intake port 112 formed on one side and the exhaust port 114 formed on the upper side, and the blowing housing 110 through the intake port 112. A blowing fan 120 that sucks in outside air and outputs it to the exhaust port 114, and a solar panel 130 installed on the outer surface of the blowing housing 110 and generating electric energy required to drive the blowing fan 120, Including a filter member 140 for filtering the outside air sucked through the intake port by the blowing fan 120,
When the blowing fan 120 is driven by electric energy generated by the solar panel 130, outside air is sucked through the air intake 112 with the blowing housing 110 and filtered through the filter member 140. It is provided to be discharged through the exhaust port 114,
The heat storage block unit 200, the heat storage housing 210 in which a transparent window 212 is formed to allow sunlight to pass through the side, and the sun installed inside the heat storage housing 210 and introduced through the transparent window 212 The heat storage member 220 that absorbs and stores the thermal energy of light, and the heat storage member 220 is penetrated in the longitudinal direction inside the heat storage housing 210 corresponding to the back surface, and the exhaust port 113 of the blower housing 110 is at the top and bottom. It includes a heating passage 230 in which upper and lower air ports 231 and 232 communicating with are opened,
The heat storage member 220 absorbs thermal energy of sunlight flowing into the transparent window 212, and the air passing through the heating passage 230 is heated by the heat storage of the heat storage member 220,
The heat storage member 220 is provided to be reversed by the turning module 400,
The turning module 400 is installed on a support shaft 410 rotatably supporting the heat storage member 220 and at both ends of the heat storage member 220 in the longitudinal direction, and in opposite directions in the thickness direction of the heat storage member 220. The eccentric compartment 420 provided as a pair at a biased position and the connecting tube 430 connecting the eccentric compartment 420 and extending so that both ends are adjacent to the inner bottom surface of the eccentric compartment 420, the eccentric compartment 430 ) A thermal expansion fluid 440 accommodated therein, and a heat insulating material 450 installed in the longitudinal direction inside the heat storage member 220 to insulate the eccentric compartment 430 in one direction,
The thermal expansion liquid 440 is accommodated in one of the pair of eccentric compartments 420, and one end of the heat storage member 220 corresponding to the eccentric compartment 420 in which the thermal expansion liquid 440 is accommodated. is located at the bottom, and one end of the heat storage member 220 corresponding to the empty eccentric compartment 420 is located at the top,
The eccentric compartment 420 disposed below the heat storage member 220 is biased toward the side corresponding to the transparent window 212, and the eccentric compartment 420 disposed above the heat storage member 220 has a heating passage 230. ) and is biased toward the corresponding side,
When the heat storage member 220 absorbs and heats the thermal energy of the sunlight flowing into the transparent window 212, the thermal expansion fluid 440 is heated in the eccentric compartment 420 located below the heat storage member 220 and is caused by thermal expansion. When the weight of the upper region compared to the lower region of the heat storage member 220 increases while moving toward the eccentric compartment 420 located above the heat storage member 220 along the connector 430, when the heat storage member 220 is reversed 180°, the sun One surface of the heat storage member 220 heated by light is located in an area corresponding to the heating passage 230 to heat air, and the other surface of the heat storage member 220 is disposed to correspond to the transparent window 212 to provide thermal energy from sunlight. Heating block system through solar light reception, characterized in that provided to accumulate.
delete delete delete According to claim 1,
Eccentric weights 240 are provided at both ends of the heat storage member 220 to be biased in the opposite direction to the eccentric compartment 420,
Heating block system through solar light reception, characterized in that provided to face the direction in which sunlight is incident in a state where the heat storage member 220 is tilted at an inclination angle by the eccentric weight 240.
According to claim 5,
The transparent window 212 is a heating block system through solar light reception, characterized in that formed in a hemispherical shape consistent with the rotation radius of the heat storage member 220 and concentric.
According to claim 1,
A water supply pipe is connected to pass through the inside of the heat storage member 220, and the water moving along the water supply pipe is heated while passing through the inside of the heat storage member 220, characterized in that it is provided to be used as hot water and heating water Heating block system through solar light reception.

Images