KR20080100319A - Solar-powered ventilation system - Google Patents

Abstract

A room ventilation and cold wind apparatus is provided to lower the temperature of indoor by flowing-in into the indoor after cooling the external air using the solar energy. The room ventilation and cold wind apparatus using the solar energy is composed of a solar heat collecting plate(1) collecting the heat from the sun, a solar collector condensation plate(2) for condensing again after concentrating the collected-heat for one place, a blowing pipe(3), and an apparatus ejecting the indoor air which is the relatively low temperature to outdoor.

Description

Indoor ventilation and cold air system using solar heat {solar-powered ventilation system}

The purpose of the present invention is to discharge the air in the hot summer room and to introduce the cool air to keep the temperature of the room in a good condition for people to live. Therefore, the present invention aims to reduce indoor temperature by injecting indoor air to the outside by using thermal convection caused by solar heat, cooling the outside air using water vaporization and cold water and ice, and then entering the room to lower the temperature of the room. .

In addition, by driving the cooler with electricity generated using the solar cell to cool the outside air to discharge the room and install a blower fan in the air inlet and outlet to maximize the air circulation.

In order to carry out the present invention, when solar heat is collected by the heat collecting plate and the end of the pipe connected to the room is heated, the heated pipe causes heat convection of the air, and the air moves from the cold side to the hot side. There may be a difference in temperature to be recruited depending on the size of the solar collector plate, but when collecting the sun to heat the air circulation pipe with a circular collector plate of about 30cm in diameter can be heated from 250 ℃ to 1,000 ℃. The higher the temperature, the more air is released from the room to the outside. The exhausted air passes through the radiator with water to cool the air supplied from the outside. At this time, the water evaporates and takes away the heat from the surroundings, so the air flowing into the room decreases the radiator temperature. .

When the air in the closed room is discharged to the outside, the room becomes empty as much space, thereby introducing air from the outside. At this time, the air coming from the outside is cooled by passing through the cold radiator, the air discharged from the room is taken through the vaporization of water to enter the room. At this time, in addition to the method by vaporization, cold cold water and ice cool the radiator to cool the air sucked into the inside.

The hotter the sun, the higher the efficiency of air circulation and cooling of the present invention.

By attaching additional solar panels to the solar heat collecting plate, the circulation motor can be installed and operated inside the pipe to discharge the air and maximize the efficiency of air circulation, and the cold water in contact with the radiator to cool the air flowing into the inside. It can be cooled by electric power by driving the motor and the compressor which is the principle of the refrigerator.

It is available 24 hours a day by using solar cells during the day and general household electricity in the evening without sun.

The representative of the existing indoor air cooling system was the air conditioner. The problem of air conditioners causes a lot of problems in global warming and environmental pollution by using a large amount of electricity and the use of freon gas series.

The present invention is environmentally friendly by cooling indoor air by using solar heat actively, and its purpose is to reduce electricity use.

In order to carry out the present invention, when solar heat is collected by the heat collecting plate and the end of the pipe connected to the room is heated, the heated pipe causes heat convection of the air, and the air moves from the cold side to the hot side. There may be a difference in temperature to be recruited depending on the size of the solar collector plate, but when collecting the sun to heat the air circulation pipe with a circular collector plate of about 30cm in diameter can be heated from 250 ℃ to 1,000 ℃. The higher the temperature, the more air is released from the room to the outside. The exhausted air passes through the radiator with water to cool the air supplied from the outside. At this time, the water evaporates and takes away the heat from the surroundings, so the air flowing into the room decreases the radiator temperature. .

When the air in the closed room is discharged to the outside, the room becomes empty as much space, thereby introducing air from the outside. At this time, the air coming from the outside is cooled by passing through the cold radiator, the air discharged from the room is taken through the vaporization of water to enter the room. At this time, in addition to the method by vaporization, cold cold water and ice cool the radiator to cool the air sucked into the inside.

The hotter the sun, the higher the efficiency of air circulation and cooling of the present invention.

By attaching additional solar panels to the solar heat collecting plate, the circulation motor can be installed and operated inside the pipe to discharge the air and maximize the efficiency of air circulation, and the cold water in contact with the radiator to cool the air flowing into the inside. It can be cooled by electric power by driving the motor and the compressor which is the principle of the refrigerator.

It is available 24 hours a day by using solar cells during the day and general household electricity in the evening without sun.

It is effective to reduce the amount of artificial electricity and to ventilate and cool the indoor air by using solar heat and sunlight, which are infinite natural energy.

Detailed embodiments for carrying out the above will be described in detail with reference to the accompanying drawings.

1 is a representative embodiment of the present invention collects the heat of the sun in the solar heat collecting plate (1) is collected in one place of the solar heat collecting condensation plate (2). The collected solar heat heats the end of the blower tube 3. When the blower tube 3 is heated, air causes heat convection, and indoor air, which is cold air, is discharged to the outside. As the air flows due to the convection of heat, the air intakes 5 located at the top of the house 10 are sucked into the warm air and passed through the air circulation and cooling device 9 through the indoor air intake pipe 14. To exit the heated blower pipe 3 through the blower pipe 4.

When air in a closed room escapes to the outside, it must be filled from the outside to fill the void. Accordingly, the suction pipe 6 is located outside the house 10 to suck in air and is cooled while passing through the air circulation and cooling device 9 to be supplied to the indoor cold air discharge pipe 7. At this time, it can be forcibly sucked through the indoor fan (8).

2 is an enlarged view of the solar heat collecting plate.

The solar heat collecting plate (1) is in the form of a concave satellite antenna to maximize the sun's reflection by the mirror of the sunlight. It can be installed on windows, balconies, or outdoors in the direction of the sun. The solar heat collecting plate 1 receives solar light 13 and collects solar heat into the solar heat collecting condensation plate 2. The surface of the solar heat collecting condenser plate 2, in which sunlight gathers, is also made of a mirror.

2 is an enlarged portion of the solar heat collecting condenser plate 2. Reflected and collected solar heat is collected into the portion to be heated 17, which is a portion painted in black at the end of the blower tube 3, to heat the blower tube 3 hot. The blower tube 3 is preferably made of a material that can withstand high temperatures. The hotly-heated blower tube 3 causes convection of heat, and the air in the room at low temperature moves to the portion 17 to be heated and is naturally discharged to the outside when heated.

3 is a view of the solar heat collecting plate 1 viewed from above. In the middle of the blower tube, the air hole 17 is drilled to allow air circulation.

'A' of FIG. 3 is a general solar heat collecting plate 1 of the present invention, and 'I' is a picture showing that the solar panel 20 is attached to the edge. The size of the solar panel may cover the whole of the solar heat collecting plate (1) or may cover only a portion as shown in the figure. The electricity produced by the solar panel 20 is used to drive the blower motor 18 and the motor 28 of the cooler of the present invention.

4 is a diagram showing that the solar heat collecting plate 1 can also be connected in parallel. If much more air circulation is needed than one solar heat collecting plate (1), it is possible to connect several by connecting the 'L'-shaped pipe (11) and the' + '-shaped pipe. Even if a plurality of solar heat collecting plate (1) is connected, it is connected to one blow pipe (4).

5 is a view showing the indoor air intake device 17 for sucking air in the room. Since the hot air of the indoor air is collected on the upper wall of the room is discharged to the outside through the indoor air intake pipe (14).

FIG. 6 is a diagram showing a blower motor device 18 to be positioned inside the pipe. 'A' is a picture showing the connection to the blowing and suction pipes, and 'I' is a picture showing the inside. It is provided with a blowing motor 19 and a blowing blade 21 therein to be driven by electricity to forcibly discharge or suck air.

7 is a view through the inside of the air circulation and cooling device (9).

The inside of the air circulation and cooling device 9 is divided into three parts by the inner screen 16. The indoor air intake pipe (14) on the left side of the figure is connected to the center part of the device that is divided into three parts from the outside of the device so that the air sucked in the room stays in the center of the device and is discharged to the outside through the blower pipe (4). do. When the outside air intake pipe 6 passes through the right side of the device and sucks in air, it moves through the air cooling radiator 15 through the air circulation and cooling device internal air passage 23 to the left space and moves to the left space. 7) The air moves to the room through.

The portion connecting both spaces of the air cooling radiator 15 is finished with a rubber packing 24 for disconnection from the center space.

In order to explain the present invention, one air cooling radiator 15 is drawn in the figure, but in actual practice, it is preferable that one or more radiators are installed.

About one third of the air cooling radiator 15 is contained in cold water or ice 22 so that the air sucked from the outside is cooled coolly.

8 is a virtual diagram showing an air flow diagram of the air circulation and cooling device 9.

The indoor air is in the middle space through the indoor air intake pipe (14) and then exits to the outside through the blower pipe (4) by the indoor air movement path (26).

The outside air stays in the right space through the outside air intake pipe 6. At this time, moisture is removed by the moisture remover 34. Dehumidifier 34 is made of paper, cotton, charcoal, cloth and the like, has a function to remove moisture in the air, can be replaced and reused in the air to dry. The dehumidified air is cooled coolly through the air cooling radiator 15 contained in the cold water or ice 22, and then collected in the left space and sent to the room through the cold air discharge pipe 7.

9 shows a cooling radiator 15.

For easy explanation of the present invention, it is expressed in a circular curved tube shape, but can be modified in various shapes.

'A' of FIG. 9 is a diagram showing a cross section of the cooling radiator 15. The external material is preferably made of stainless steel that is not rusted with water, and has no space inside. 'I' is a picture showing a cloth covering the outer surface of the cooling radiator (15). The reason why the outer surface of the cooling radiator 15 is wrapped with a cloth is to allow the cold water and ice 22 to cover the entire cooling radiator 15 on the cloth. The wet cloth 27 is intended to easily take away the heat of the surroundings when the air introduced from the room is discharged and vaporized as the laundry is discharged.

10 is a perspective view showing the external appearance of the air circulation and cooling device (9).

 Cold water and ice supplemental swing door 36 is provided so that the user can directly refill the cold water and ice (22). The dehumidifier 34 may replace the dehumidifier 34 by opening the dehumidifier replacement cover 35 when the dehumidifier 34 is no longer serving as dehumidification. The right outer wall 38 of the air circulation and cooling device may enter the air by the suction pipe 6, but it is possible to replace the wall itself with an external air suction screening film 37 to suck the air into the entire wall surface. The outer air suction shielding membrane 37 serves as a shielding membrane in the form of a net to prevent the internal moisture remover 34 from leaving the air circulation and the cooling device 9.

11 is a perspective view showing a state in which the cooler 33 is attached to the air circulation and cooling device 9. The present invention can produce electricity by solar convection and solar cells. The electricity generated is driven by the motor 28, which is a basic principle of the refrigerator, to compress the liquid refrigerant by using the compressor 29, and then install the evaporator 31 in the cold water and ice 22 through the condenser 30 to cool it. The water contacted by the radiator 15 can be cooled coolly. The electricity produced by the solar cell can be installed in the pipe of the blower 18 to forcibly control the discharge of indoor air and the suction of outdoor air.

12 is a perspective view showing a state in which the cooler 33 is installed in the air circulation and cooling device (9).

The cooler 33 is located at the lower end of the air circulation and cooling device 9 and the condenser 30 is attached to the condenser radiator grill 39 and attached to the rear of the air circulation and cooling device 9. The cooler pipe 32 from the cooler 33 is connected to the pipe of the condenser 30.

The present invention as described above is a basic embodiment

Solar heat is collected from the sun to the solar heat collecting plate 1 to heat the blower tube 3, and the heated blower tube 3 causes heat convection to discharge the indoor air to the outside. The discharged air vaporizes the water absorbed in the cloth 27 that covers the outer portion of the air cooling radiator 15 of the air circulation and cooling device 9 to cool the air cooling radiator 15 when discharged. . When the air in the closed room escapes to the outside, the outside air is sucked in to fill the empty space in the room, and the air is cooled while passing through the air cooling and cooling radiator (15) of the air circulation and cooling device (9) and discharged as cold air to the room. It makes the indoor air cool.

Attaching the solar panel 20 to the solar heat collecting plate 1 installs an electric cooler 33 in the air circulation and cooling device 9 to cool the intake air, and is forced by the blower 18. Circulates air.

In the case of the sun, the air is cooled by electricity generated by solar cells, and in the absence of the sun, the air is cooled by general electricity.

As described above, although the indoor ventilation and cold air device using solar heat according to a preferred embodiment of the present invention is shown in accordance with the above description and drawings, this is only an example and within the scope not departing from the technical spirit of the present invention. It will be appreciated by those skilled in the art that various changes and modifications can be made in the art.

The present invention can replace or supplement the existing air-conditioning and cold air devices that are driven by conventional electricity, and because it uses only solar heat, no electricity is used, or some devices can be driven using solar cells. Can contribute.

It can be used in apartments, offices, factories, businesses, etc.

1 is a virtual diagram showing an embodiment of the present invention.

Fig. 2 is a cross-sectional view showing the solar heat collecting plate 1. 'A' is an enlarged view of the dotted line portion of the cross name.

'A' of FIG. 3 is a view of the solar heat collecting plate 1 viewed from above. 'I' is a figure showing a state in which the solar panel 20 is attached to the solar heat collecting plate (1).

4 is a view showing the solar collector plate 1 is connected in parallel by the 'L'-shaped,' + '-shaped piping.

5 is a perspective view showing a device for sucking indoor air.

6 is a perspective view illustrating a blower motor installed between an inlet pipe and a discharge of air operated by a solar cell. 'I' is a perspective view of the blowing motor device.

7 is a perspective view showing the interior of the air circulation and cooling device 9.

8 is an imaginary diagram showing the flow of air in the air circulation and cooling device 9.

9 is a plan view showing a radiator 15 for air cooling. 'I' is a figure showing the appearance of wrapping the outer portion of the air cooling radiator 15 with a cloth (27).

10 is a perspective view showing the outer shape of the air circulation and cooling device 9.

11 is a plan view showing that the cooler 33 is attached to the air circulation and cooling device 9.

12 is a perspective view showing that the cooler 33 and the condenser radiator grill 39 are attached to the air circulation and cooling device 9.

* Description of the symbols for the main parts of the drawings *

1. solar collector 2. solar collector condenser 3. blower

4. Blowing pipe 5. Air inlet 6. External air inlet

7. Cold air exhaust pipe 8. Fan 9. Air circulation and cooling system

10. House 11. 'L' shaped pipe 12. '+' shaped pipe

13. Sunlight 14. Indoor Air Suction Pipe 15. Radiator for Air Cooling

16. Inner Screen 17. Solar Heating Part 18. Blowing Motor

19. Blowing motor 20. Solar panel 21. Blowing motor blade

22. Cold water and ice 23. Air passages in the air circulation and cooling system

24. Rubber packing 25. External air path 26. Indoor air path

27. Cloth 28. Motor 29. Refrigerant condenser 30. Condenser 31. Evaporator

32. Chiller piping 33. Chiller unit 34. Dehumidifier

35. Cover for replacing dehumidifier 36. Casement door for refilling cold water and ice

37. Blanking membrane for intake of outside air 38. Right outside wall for air circulation and cooling

39. Condenser radiator grille 40. Handle 41. Handle

Claims (2)

In the indoor ventilation and cold wind device using solar heat, the end of the blower tube (3) is heated by a solar heat collecting plate (1) that collects heat from the sun and a solar heat collecting condenser (2) that collects and condenses the collected heat into one place. A device for exhausting indoor air having a relatively low temperature to the outside by creating a convection phenomenon of heat;  Cold water and ice (22) of the air circulation and cooling device (9), which cools the air sucked from the outside when the indoor air escapes to the outside, makes the air cooling radiator (15) primarily cool, and Water 22 absorbed by the cloth 27 surrounding the gas is evaporated and discharged by the air flowing out of the room to absorb surrounding heat to cool the air cooling radiator 15; The air that enters the room from the outside to the room is cooled by passing through the evaporation phenomenon caused by the air discharged from the inside to the outside and the air cooling radiator (15) cooled by the cold water and ice (22) to circulate the indoor air and generate cold air. Device An apparatus for generating electricity from sunlight by attaching the solar panel 20 to the solar heat collecting plate 1 in claim 1; Attached to the generated electric furnace air circulation and cooling device (9) to install a cooler 33 using a high-pressure liquid refrigerant and to drive the motor 28 and the compressor 29 to drive the cold water and ice 22 to the evaporator ( A cooling device for making electrically cold cold water by using 31) to cool the air cooling radiator 15 to cool the air sucked into the room from the outside; The blower motor device 18 is added to the blower pipe 4 discharged indoors by the electricity generated from the solar cell and the suction pipe 6 sucked into the room indoors, thereby forcibly discharging the air by the blower electric motor 19. A device that makes outdoor air cool and cold air into the room and circulates indoor air to the outside

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