KR20120136684A - Solar heater - Google Patents

Abstract

PURPOSE: A solar heat blower is provided to use solar heat after sunset by holding the solar heat in the daytime, and to be attached to a wall with a small volume. CONSTITUTION: A solar heat blower comprises a frame(100), a rotary plate(200), a sealing member(300), an inflow hole(400), and a discharge hole(500). The sealing member expands or contracts a sealed space while the rotary plate rotates. The inflow hole guides the indoor air to the sealed space. The discharge hole discharges the heated air in the sealed space to the inside of a building. The sealing member is opened when the lower part of the rotary plate rotates to be inclined in the opposite direction of the frame so that the sealed space is expanded. The air in the sealed space is heated by solar heat which is emitted to the rotary plate.

Description

Solar Heater {SOLAR HEATER}

The present invention relates to a solar warmer, particularly a solar warmer that heats the interior of a building using solar heat in a cold season, such as winter.

Currently, human beings face the depletion of fossil fuels, and the efficient use of energy and active use of alternative energy are facing challenges in preparation for the high oil prices that will inevitably follow.

Therefore, much research has been made on solar energy, which is the most viable alternative to petroleum oil, and is infinitely clean energy that can be used almost infinitely if only suitable solar energy is supplied per unit area without consuming energy resources. come.

Conventionally, solar water heaters, solar generators, and the like are used using such solar energy.

However, such a solar water heater or a solar generator had a problem that the installation is reluctant because of the high cost generated during the initial installation.

In order to solve this problem, conventionally, a solar heater is proposed to reduce the heating cost of the home by simply increasing the indoor temperature even during the daytime in winter by simply installing at a low installation cost.

1 is a cross-sectional view showing the structure of a conventional solar thermal fan.

As shown in FIG. 1, a conventional solar warmer includes a frame 10 formed of a rectangular box and mounted on a wall of the building C, and a transparent body mounted on the front of the frame 10 to transmit sunlight ( 20); An inlet hole 30 through which air in the interior of the building C is introduced into the frame 10; Air inside the frame 10 was heated by the sunlight passing through the transparent body 20 was composed of a discharge hole 40 for discharging to the interior of the building (C).

Conventional solar heat fans have been used mounted south facing to the sun in a variety of buildings, such as containers, prefabricated panel houses.

However, since the solar heater is installed on the wall surface of the building (C), since the transparent body 20 is disposed perpendicular to the ground, the solar heat fan can absorb solar heat than when it is vertical because the incident angle of sunlight passing through the transparent body is small. There was a problem with this shrinking.

In addition, in order to increase the temperature of the interior of the building (C), a lot of air needs to be heated and sent to the interior of the building (C). In order to do so, the volume of the frame 10 becomes large, thereby using only a winter season. And when not in use, the volume is too large to be difficult to store, there was a problem that harm the glazing of the building (C).

And there was a problem that can not be used after sunset.

The present invention is to solve the above problems, when the warm air is inclined from the wall of the building to supply the warm air to the interior of the building, solar heat efficiently supplies air to the interior of the building, and a large amount of air to heat When the storage is in close contact with the wall, the volume becomes smaller and easier to store, and the purpose is to provide a solar hot air heater that can be used even after sunset by storing the solar heat of the day.

In order to achieve the above object, the solar thermal fan of the present invention includes a frame mounted to a building; A rotary plate whose upper end is hinged with the upper end of the frame and the lower end rotates inclinedly; A sealing member having one end surrounding the lower surface and the side of the rotating plate, and the other end connected to the frame, the sealing member extending or contracting a sealed space formed therein according to the rotation of the rotating plate; An inlet hole formed in the frame to allow indoor air of the building to flow into the closed space; A discharge hole formed in the frame to discharge heated air of the closed space into the interior of the building; Consisting of the lower end of the rotating plate to the center When rotated obliquely in the opposite direction of the frame, the sealing member is developed so that the sealing space is expanded, and the air in the sealing space is heated by solar heat irradiated to the rotating plate. .

A heat storage material disposed in the sealed space to store heat in the sealed space; And further comprising:

The rotating plate is characterized in that consisting of a transparent body through which the sunlight is transmitted.

The rotating plate is characterized in that made of iron reinforced glass.

The sealing member is formed with a corrugation so that it can be developed and folded by the rotation of the rotating plate, the frame is equipped with a binding member for fixing the rotating plate, the rotating plate is rotated by the sealing member formed wrinkles When the bottom of the rotating plate is in close contact with the frame, The binding member The rotating plate is fixed to the frame.

At least one of the inlet hole or the outlet hole is provided with a valve to selectively block the circulation of air, and at least one of the inlet hole or the outlet hole is equipped with a fan for circulating the air, the inlet The ball is disposed in the lower portion of the frame, the discharge hole is characterized in that disposed on the upper portion of the frame.

According to the solar warmer of the present invention as described above has the following effects.

When the upper end of the rotating plate and the upper end of the frame is hinged to the lower end of the rotating plate is rotated obliquely while the solar heat is well irradiated to the inclined rotating plate to heat the air in the sealed space, when the lower end of the rotating plate, The sealing member is developed to expand the sealed space, thereby heating a large amount of air in the sealed space by solar heat and discharging it to the discharge hole, thereby increasing the indoor temperature of the building with a large amount of heated air.

By arranging the heat storage material in the sealed space, the heat storage material is heated by the solar heat during the sunshine time to store the heat, and the stored heat after sunset heats the air in the sealed space, the heated air through the discharge hole While being discharged to the interior of the building, there is an effect of raising the temperature of the interior of the building even after sunset.

Since the rotating plate is made of a transparent body, sunlight is transmitted through the rotating plate to directly heat the air in the sealed space and the heat storage material.

By arranging the rotating plate with iron-reinforced glass, the transparency of the rotating plate is high, so that the sunlight is well transmitted, thereby effectively heating the air and the heat storage material in the sealed space.

By fixing the rotating plate in close contact with the frame to the frame with the binding member, there is an effect of preventing the rotating plate from being unfolded arbitrarily when not in use.

The air heated by the fan in the sealed space is rapidly circulated to the interior of the building through the discharge hole disposed in the upper part of the frame, and the cold air of the building is sealed through the inlet hole disposed in the lower part of the frame. By entering the space to be heated by solar heat, there is an effect of maintaining a constant temperature while increasing the room temperature quickly.

1 is a cross-sectional view showing the structure of a conventional solar thermal fan.
Figure 2 is a state of use showing the state of use according to the embodiment of the present invention solar thermal fan.
Figure 3 is a cross-sectional view AA of Figure 3 according to an embodiment of the present inventors solar thermal fan.
Figure 4 is a sectional view showing a storage state according to an embodiment of the present invention solar heat fan.

Figure 2 is a state diagram showing the use state according to an embodiment of the solar heat blower of the present invention, Figure 3 is a cross-sectional view AA of Figure 3 according to an embodiment of the solar heat blower of the present invention, Figure 4 is an embodiment of the solar heat blower of the present invention It is sectional drawing which shows the storage state along.

As illustrated in FIGS. 2 to 4, the solar thermal air heater according to the embodiment of the present invention includes a frame 100, a rotating plate 200, a sealing member 300, an inlet hole 400, an outlet hole 500, and heat storage. It comprises ash 600.

The frame 100 is formed in a rectangular box shape is mounted on the wall surface of the building (C).

The frame 100 is formed in a rectangular box shape in order to be able to store the components of the solar warmer inside the frame 100 therein.

A binding member 110 is disposed below the frame 100 as shown in FIG. 4.

The binding member 110 serves to fix the lower portion of the rotating plate 200 in the frame 100.

The binding member 110 is fixed to the rotating plate 200 using a known technique, so a detailed description thereof will be omitted.

The rotating plate 200 is formed of a rectangular plate material is formed to be inserted into the frame 100.

The rotating plate 200 may be made of an opaque body.

However, it is preferable to form the rotating plate 200 as a transparent body as in the present embodiment so that sunlight can be transmitted well.

In particular, the rotating plate 200 to be made of iron-reinforced glass of the transparent body.

Among the iron tempered glass, the low iron tempered glass is used to increase the transparency of the rotating plate 200 so that the transmittance of solar light is improved.

The rotating plate 200 is hinged to the upper end inside the upper end of the frame 100, is disposed slightly spaced apart from the wall of the building (C).

The lower end of the rotating plate 200 is inclined in the opposite direction of the frame 100 in the frame 100 by the hinge coupling of the upper end.

One end of the sealing member 300 surrounds the bottom surface and the side surface of the rotating plate 200, and the other end is connected to the frame 100 to form a sealed space S therein.

The sealing member 300 may be deployed and folded by the rotation of the rotating plate 200.

In this embodiment, the hermetic member 300 has a corrugation in order to enable the deployment and folding.

The sealing member 300 expands or contracts the sealed space S formed therein according to the rotation of the rotating plate 200.

The stopper 120 is disposed on a side surface of the rotating plate 200 so that the rotating plate 200 is not folded when the sealing member 300 is expanded while the sealing member 300 is expanded.

As shown in FIGS. 2 to 4, the stopper 120 is rotated and folded only in one direction. When the stopper 120 is rotated a little more than 180 degrees, the stopper 120 is no longer extended or folded.

One end of the stopper 120 is hinged to the rotating plate 200, the other end is hinged to the frame 100, when the rotating plate 200 is extended, the stopper 120 is 180 degrees or more Rotated and unfolded and no longer unfolded or folded, and when folding the rotary plate 200, the hinge engaging portion in the middle of the stopper 120 is rotated by more than 180 degrees fixed to the 180 degrees or less in the direction of rotation to the One end and the other end of the stopper 120 is rotated and folded.

Detailed structure for this is sufficient to use a conventional general structure.

The inflow hole 400 is a passage through which indoor air of the building C flows into the closed space S.

The inflow hole 400 is disposed below the frame 100 to allow the cold air of the building C to flow into the closed space S.

The discharge hole 500 is a passage through which the heated air of the closed space S is discharged into the interior of the building C.

The discharge hole 500 is disposed above the frame 100 to discharge air heated by the sun from the closed space S to the interior of the building C.

A valve 410 and a fan 510 are disposed in the discharge hole 500 or the inlet hole 400.

The valve 410 is installed in the inlet 400 and the outlet 500 to prevent the indoor air of the building (C) from being circulated to the closed space (S) when not used.

The valve 410 prevents the air in the sealed space S from being circulated during the heating time, and opens the air into the interior of the building C when the air in the sealed space S is heated. It allows the air to circulate.

That is, the valve 410 controls to block or circulate the air in the closed space (S) and the indoor air of the building (C).

In addition, the fan 510 is installed in the discharge hole 500, and the air heated in the closed space S by the fan 510 is rapidly circulated to the interior of the building C to be spread.

Although the valve 410 is installed in both the inlet hole 400 and the outlet hole 500, unlike the present embodiment, the valve 410 of the inlet hole 400 or the outlet hole 500 It can also be installed and used in either.

And although the fan 510 is also installed only in the discharge hole 500, unlike the present embodiment, the fan 510 is installed only in the inlet hole 400, or the inlet hole 400 and the discharge hole. All of them can be installed and used at 500.

The heat storage material 600 is formed in a plate shape is disposed in the closed space (S).

The heat storage material 600 is formed smaller than the width of the sealed space (S) so that the air in the sealed space (S) is evenly circulated back and forth of the heat storage material (600).

The heat storage material 600 is heated by the solar heat during the sunshine hours to store the heat, the heated air by heating the air in the closed space (S) with the stored heat after sunset the building through the discharge hole (500) (C) As it is discharged into the room, the temperature of the building (C) is increased even after sunset.

The heat storage material 600 is preferably formed of a copper plate made of metal having a property of storing heat well.

The heat storage material 600 is hinged to the upper end of the frame 100, as shown in Figure 3, the lower portion is connected to the lower portion of the rotating plate 200 by a predetermined amount spaced hinge the rotating plate 200 When the rotation by the combination is also formed to be inclined to rotate the heat storage material 600 as well, so that the heat storage material 600 is heated efficiently by receiving the sunlight coming into the rotating plate 200 in direct sunlight.

It describes the use method and the operation method of the solar hot air heater of the present invention having such a configuration.

Containers, prefabricated panels, pensions, mobile offices, such as a variety of buildings (C) to be used as mounted on the outer wall facing the sun well as shown in FIG.

This solar heat fan is used in the cold season such as winter or early autumn and early spring.

As shown in FIG. 3, the solar warmer mounted on the wall of the building C is operated. First, the rotary plate 200 fixed to the binding member 110 disposed below the frame 100 is operated. Release the lock.

As shown in FIG. 3, the rotating plate 200 released as described above has a lower end of the rotating plate 200 as the center. Rotate inclined in the opposite direction of the frame 100.

As shown in FIG. 3, the rotating plate 200 is rotated obliquely so that the incident angle of the sunlight shining through the rotating plate 200 is close to the vertical, so that the sunlight shines efficiently into the closed space S. do.

At this time, the rotating plate 200 is rotated, the sealing member 300 is expanded to expand the sealed space (S).

At this time, the valve 410 of the discharge hole 500 is blocked, the valve 410 of the inlet hole 400 is opened, and when the air in the closed space S is heated, the discharge hole 500 The valve 410 is also opened to allow the heated air to be discharged into the interior of the building (C).

The air in the expanded sealed space S is heated by the sun irradiated to the rotating plate 200.

Thus, the sealing member 300 is deployed to accommodate a large amount of air in the expanded space of the sealed space (S) it is possible to heat a large amount of air for a short time.

As the rotating plate 200 is rotated and the sealing member 300 is developed, when the sealing space S is expanded, the rotating plate 200 is fixed to the stopper 120 disposed on the side thereof so that the rotating plate 200 is not folded.

As described above, the upper end of the rotating plate 200 and the upper end of the frame 100 are inclinedly rotated by the hinged lower end of the rotating plate 200 so that the solar heat is well irradiated to the inclined rotating plate 200 to provide a closed space (S). When the air of the heating), and the lower end of the rotating plate 200 is rotated, the sealing member 300 is expanded to expand the sealed space (S) as a large amount of air in the sealed space (S) By heating with solar heat to discharge a lot of air heated in the discharge hole 500 has the effect of increasing the room temperature of the building (C) quickly.

And the heated air is discharged into the interior of the building (C) through the discharge hole 500, the cold air in the interior of the building (C) through the inlet (400) the closed space (S) When it is introduced into the solar heat is discharged to the discharge hole 500 again while the natural circulation of the atmosphere to warm the interior of the building (C).

The fan 510 is attached to the discharge hole 500 as shown in FIGS. 3 to 4 in order to circulate better than the heated air in the closed space (S).

The fan 510 attached to the discharge hole 500 of the building (C) through the discharge hole 500, the air heated in the closed space (S) is disposed on the upper portion of the frame 100 To discharge quickly into the room, the cold air of the building (C) is introduced into the closed space (S) through the inlet hole 400 disposed under the frame 100 to be heated by solar heat, While rapidly increasing the room temperature of the building (C) has the effect of maintaining a constant temperature.

In addition, the heat storage member 600 is inclined at an angle along the rotating plate 200 in the sealing member 300 so as to be heated by sunlight entering the rotating plate 200 as shown in FIG. 3.

The heat storage material 600 is heated by the solar heat during the sunshine time to store heat, the heat stored after sunset heats the air in the closed space (S) heated air through the discharge hole 500 While being discharged to the interior of the building (C), the temperature of the interior of the building (C) increases even after sunset, thereby heating.

And when the weather is warm and not used, such as seasons do not need heating, when the rotating plate 200 is released to the stopper 120 and rotated in the direction of the frame 100, the sealing member 300 is folded, the inside The closed space (S) of the contraction.

Then, the inlet hole 400 and the outlet hole 500 are blocked by the valve 410 to block the circulation of air.

When the rotating plate 200 is in close contact with the frame 100, the rotating plate 200 is fixed to the frame 100 by the binding member 110, as shown in FIG. 4. Do not rotate it to straighten it.

As such, by storing the components of the solar warmer inside the frame 100 with the binding member 110, the volume of the building C is neat and greatly reduced to store on the wall of the building C so as not to spoil the glazing of the building C. It does not take up space.

The solar thermal air blower of the present invention is not limited to the above-described embodiments, and may be variously modified and implemented within the range in which the technical idea of the present invention is permitted.

100: frame, 110: binding member, 120: stopper
200: turntable
300: sealing member
400: inlet hole, 410: valve
500: vent hole, 510: fan
600: heat storage material, S: confined space, C: building

Claims (6)

A frame mounted to the building;
A rotary plate whose upper end is hinged with the upper end of the frame and the lower end rotates inclinedly;
A sealing member having one end surrounding the lower surface and the side of the rotating plate, and the other end connected to the frame, the sealing member extending or contracting a sealed space formed therein according to the rotation of the rotating plate;
An inlet hole formed in the frame to allow indoor air of the building to flow into the closed space;
A discharge hole formed in the frame to discharge heated air of the closed space into the interior of the building; Lt; / RTI >
When the lower end of the rotating plate is rotated inclined in the opposite direction of the frame around the upper end, the sealing member is deployed to expand the sealed space, the air in the sealed space is heated by solar heat irradiated to the rotating plate Solar heat fan, characterized in that. The method of claim 1,
A heat storage material disposed in the sealed space to store heat in the sealed space; Solar warmer, characterized in that further comprises a. The method of claim 1,
The rotating plate is a solar heat fan, characterized in that made of a transparent body through which the sunlight is transmitted. The method of claim 3,
The rotating plate is a solar heat fan, characterized in that made of iron reinforced glass. The method according to any one of claims 1 to 4,
The sealing member is wrinkled to be developed and folded by the rotation of the rotating plate,
The frame is equipped with a binding member for fixing the rotating plate,
When the rotating plate is rotated by the sealing member formed in the corrugation and the lower end of the rotating plate is in close contact with the frame, the binding member is fixed to the frame to the solar heat fan. The method according to any one of claims 1 to 4,
At least one of the inlet or outlet hole is formed with a valve to selectively block the circulation of air,
Any one or more of the inlet or outlet hole is equipped with a fan for circulating air,
The inlet hole is disposed in the lower portion of the frame, the exhaust hole is a solar heat fan, characterized in that disposed on the upper portion of the frame.

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