KR20190130698A - Horn waveguide panel for guiding solar radiation energy and housing using the same - Google Patents

Abstract

According to the present invention, a horn waveguide panel for guiding solar radiant energy comprises: an external transparent plate formed with a flat plate or a curved plate and arranged outwards; an internal transparent plate formed with the flat plate or the curved plate and arranged inwards; and a plurality of horn waveguides arranged to be adjacent to each other under the external transparent plate. The horn waveguides are formed in the shape of a corn of which an upper portion is wide and a lower portion is provided with a narrow hole, a triangular pyramid, a square pyramid, a rectangular pyramid, or a polygonal pyramid. An internal side of the horn waveguides is formed of or coated with an aluminum thin film or a deposited film.

Description

Horn waveguide panel for guiding solar radiation energy and housing using the same

The present invention relates to a horn waveguide panel for inducing solar radiation and a housing using the same. More particularly, the present invention relates to a horn waveguide panel and a housing using the same to induce solar radiation into a facility and prevent radiant energy from leaving the facility.

Recently, due to global warming and depletion of fossil fuels, countries around the world are implementing policies to save energy and prevent global warming. Accordingly, the industry is actively working on developing technologies to improve energy saving efficiency and reduce greenhouse gases. have.

In 2015, the Conference of the Parties to the Climate Change Convention in Paris concluded an international agreement to prevent global warming by reducing greenhouse gas emissions, including carbon dioxide, to prevent global warming, and joint efforts to reduce greenhouse gases to prevent global warming. Agreed to: Since then, the government has negotiated reduction quotas for greenhouse gas reductions, and has been making efforts to reduce greenhouse gas emissions by reassigning each country to an energy-using company. .

However, even though countries are given incentives such as policy funds, they are hesitant to install reduction technology facilities immediately, but are unable to actively purchase and install them.

This is because most of the time it takes to recover the costs of purchasing and installing facilities for improving energy efficiency and reducing greenhouse gas emissions is longer than five years.

In particular, in the field using solar radiation, solar radiation is obtained by a solar power generator or a solar heat collecting plate, but there is also a problem that the energy loss rate is very high during several energy phase conversion processes. In addition, the glass plant cultivation facility, vinyl house, the transparency decreases, the use efficiency of solar radiation waves decreases, and it is a situation that a separate cover is installed because it is not insulated at night or winter.

Korean Patent Laid-Open Publication No. 2003-0051704 provides a solar roof or wall surface, comprising a plurality of slabs, including an outer layer that transmits radiant heat and an inner layer that absorbs radiant heat, and a pipe thereunder, wherein the inner layer Heat absorbed by the heat sink is configured to heat the heat transport fluid circulating through the pipe.

Korean Patent Publication No. 10-0896385 discloses a solar collector having a double window, and is designed to improve the inclination angle of the heat absorbing plate, and the solar radiation is transferred to the heat absorbing plate, and heat is transferred from the heat absorbing plate to the heat medium circulation tube. have.

Therefore, the development of a good cost-effective transparent panel that can easily use the solar radiation that is poured infinity by solving the various problems is required.

1. Laid-Open Patent Publication No. 2003-0051704 2. Korean Patent Publication No. 10-0896385

Accordingly, the present invention provides a horn waveguide panel that prevents radiant energy from going out of the facility while inducing solar radiation to enter the facility, and a housing using the same, thereby greatly reducing the recovery period of the facility cost with high thermal efficiency.

The horn waveguide panel for inducing solar radiation according to the present invention comprises an outer transparent plate made of a flat plate or curved plate and disposed on the outside, an inner transparent plate made of a flat plate or curved plate and disposed on the inside, and the outer transparent plate. It comprises a plurality of horn waveguides disposed in contact with each other under the plate, the horn waveguide is in the shape of a cone, triangular pyramid, square pyramid, rectangular pyramidal or polygonal pyramid having a wide upper portion and a narrow hole in the lower portion The inside of the horn waveguide is made of an aluminum thin film or a deposition film.

The horn waveguide panel for inducing solar radiation according to the present invention includes an auxiliary reflecting plate which is erected in a vertical direction on one side of an upper portion of the outer transparent plate so that the angle can be changed.

In the horn waveguide panel for inducing solar radiation according to the present invention, a waveguide for reflecting radiation waves is attached to a portion of the inner transparent plate except a hole in the lower portion of the horn waveguide.

The horn waveguide panel for inducing solar radiation according to the present invention is configured such that the reflection angle at which the sunlight is reflected from the horn waveguide is 60 degrees or more, and the horn waveguide panel is configured to change inclination according to the altitude of the sun. .

A housing using solar radiation according to the invention comprises the horn waveguide panel according to the invention on at least one of its side or top surface.

By applying the horn waveguide panel and the housing using the same according to the present invention, it is possible to induce the solar radiation to enter the inside of the installation while preventing the radiant energy from going out of the installation, it is possible to significantly reduce the recovery period of the equipment cost with high thermal efficiency.

1 schematically shows a horn waveguide panel for inducing solar radiation of the present invention and a housing using the same.
2 is a horn waveguide panel for inducing solar radiation according to the present invention, and shows a state in which an auxiliary reflector is installed in a flat panel.
3 is a horn waveguide panel for inducing solar radiation according to the present invention, and shows a state in which an auxiliary reflector is installed in a curved panel.

1 schematically shows a horn waveguide panel 1 for inducing solar radiation of the present invention and a housing 20 using the same.

In the present invention, the horn waveguide panel 1 is provided in order to improve the solar radiation energy acquisition efficiency, that is, to increase the focusing efficiency of the solar radiation energy. The horn waveguide panel 1 includes an outer transparent plate 3 disposed on an outer side, an inner transparent plate 5 disposed on an inner side, and a plurality of horn waveguides 7 disposed in contact with each other under the outer transparent plate 3. )

A dehumidifying agent is provided between the outer transparent plate 3 and the inner transparent plate 5 of the present waveguide panel 1 to remove water condensation that reduces the transmittance of solar radiation waves, or the inner transparent plate ( It is preferable to provide a vent hole in 5) or to select the inner transparent plate 5 as a transparent plate of a hygroscopic material (PVA resin plate or cellulose acetate film) to suppress dew formation.

The outer transparent plate 3 is selected from a transparent plate such as a plate glass or a transparent polyacrylic plate, and a washing apparatus or air for removing fine dust or foreign matter accumulated on the outer transparent plate 3 to increase the radiation inflow rate of solar radiation waves. It is preferable to install an injection device.

The horn waveguide 7 has a funnel shape with a wide top and a narrow waveguide passage 7a at the bottom. The inside of the funnel shape of the horn waveguide 7 is made of or coated with a thin film or a deposition film made of aluminum having a high reflectance of radiation.

  The funnel shape of the horn waveguide 7 is conical, triangular pyramid, square pyramidal, rectangular pyramidal or polygonal. In particular, when the horn waveguide 7 is formed into, for example, an elongated rectangle (cross section is triangular in shape), the number of waveguides can be reduced, thereby simplifying work. In this case, the cross-sectional shape may be triangular. The overall height in the horn waveguide 7 can be set to 10 cm, for example, the actual height is adjustable as needed. In addition, it is preferable to configure the reflection angle at which the sunlight is reflected to be 60 degrees or more so that the radiant energy can be smoothly guided to the inside. Accordingly, when the upper portion of the horn waveguide is large, the lower waveguide passage 7a is narrowed. In order to increase the height.

In the horn waveguide panel 1 having the above configuration, the radiant energy of the sun is guided down while being reflected by the inner surface of the horn waveguide 7, and passes through the wide upper space of the horn waveguide 7 to the narrow waveguide passage below. It enters into the housing 20 through 7a).

As shown, a plurality of horn waveguides 7 are closely connected to each other so that solar radiation is induced by the horn waveguide 7 and delivered to the receptor 9 inside the housing 20 that receives the solar radiation. . Except for the waveguide passage 7a of the horn waveguide 7, a waveguide made of a waveguide material, such as an aluminum thin film, which reflects radiant energy to the inner transparent plate 5 of the horn waveguide panel 1 ( 11) or by using a waveguide material outside the funnel shape of the horn waveguide (7), radiant energy induced into the housing (20) does not go out. The inner wall of the housing 20 may also attach the waveguide 11. That is, the waveguide 11 blocks the solar radiation entering the housing from going out again.

The housing 20 using solar radiation energy according to the present invention includes the horn waveguide panel 1 according to the present invention in whole or in part on at least one of a side surface and an upper surface thereof.

The horn waveguide panel 1 provided in the housing 20 may also change the inclination according to the altitude of the sun. It is preferable to adjust the inclination of the horn waveguide panel 1 according to the season or time because sunlight is highly efficient in directing sunlight to the horn waveguide panel 1.

The receptor 9 inside the housing 20 for receiving the solar radiation may be, for example, a cultivated plant, an article to be dried, or an internal space as a workplace.

FIG. 2 shows a horn waveguide panel 1 for inducing solar radiation according to the present invention, in which an auxiliary reflector 30 is installed in a flat panel.

The horn waveguide panel 1 includes an auxiliary reflecting plate 30 that is erected in a vertical direction on one side of the upper side of the outer transparent plate 3 so that the angle can be changed.

The auxiliary reflector 30 is hinged at one end and the other end of the horn waveguide panel 1, and is a device for maximizing the solar radiation wave inflow rate as the altitude of the sun varies, such as morning, noon, and afternoon.

The auxiliary reflector 30 may be formed by depositing an aluminum thin plate or film on a metal plate or a resin plate or using an aluminum plate, and may be a material capable of reflecting or inducing all infrared rays, ultraviolet rays, and visible rays of solar radiation. .

The auxiliary reflector 30 has a hinge structure for adjusting the tilt according to the change in the sun's altitude, and may include a motor and an actuator. It is also possible to automatically adjust the inclination over time, it may be provided with a so-called sunflower sensor device to measure the altitude of the sun to adjust the inclination of the auxiliary reflector 30 accordingly.

Looking at the operation of the auxiliary reflector 30, in the upper part of the horn waveguide panel, for example, tilt the auxiliary reflector 30 mounted on the east side at the time of sunrise at the east and gradually upright until noon, the auxiliary reflector mounted on the west side (30) can be tilted to the west to maximize the efficiency of radiation inflow of solar radiation in the morning, noon and afternoon into the application.

3 is a horn waveguide panel 1 for inducing solar radiation according to the present invention, and shows a state in which an auxiliary reflector 30 is installed in a curved panel.

The horn waveguide panel 1 having such a curved surface is suitable for a roof of a facility requiring solar radiation, and may be suitably used, for example, in a crop growing facility, but is not limited thereto.

The auxiliary reflecting plate 1 is fixed to the center portion, for example, in the installation consisting of the curved waveguide panel 1 is curved or dome-shaped, so as to maximize the inflow rate of the solar radiation wave as the altitude of the sun, such as morning, noon, afternoon To improve, the slope can be changed.

 In the curved or domed horn waveguide panel 1, the auxiliary reflector 30 is inclined eastward at sunrise, is vertically at noon, and tilted west until dusk, and changes in sun altitude in the morning, noon and afternoon In order to increase the inflow rate of solar radiation into the installation.

The auxiliary reflector 30 has a hinge structure for adjusting the tilt according to the change in the sun's altitude, and may include a motor and an actuator. It is also possible to automatically adjust the inclination over time, it may be provided with a so-called sunflower sensor device to measure the altitude of the sun to adjust the inclination of the auxiliary reflector 30 accordingly.

In addition, the sunflower sensor device can be configured to drive a plurality of auxiliary reflecting plate by installing only one set in one application equipment.

1: horn waveguide panel
3: outer transparent plate
5: inner transparent plate
7: horn waveguide
9: acceptor
11: wave guide
20: housing
30: secondary reflector

Claims (5)

It comprises an outer transparent plate made of a flat plate or curved plate and disposed on the outside, an inner transparent plate made of a flat plate or curved plate and disposed inside, and a plurality of horn waveguides disposed in contact with each other under the outer transparent plate. The horn waveguide has a conical shape having a wide upper portion and a narrow hole at a lower portion thereof, or has a triangular pyramid, square pyramid, rectangular pyramidal or polygonal pyramid shape, and the inside of the horn waveguide is made of an aluminum thin film or a deposition film. The horn waveguide panel, which is made or applied, induces solar radiation.
The horn waveguide panel according to claim 1, further comprising an auxiliary reflecting plate which is erected in a vertical direction on one side of the upper side of the outer transparent plate to enable an angle change.
The horn waveguide of claim 1, wherein the horn waveguide is configured such that a reflection angle of sunlight reflected by the horn waveguide is 60 degrees or more, and the horn waveguide panel is configured to change inclination according to the altitude of the sun. panel.
The horn waveguide panel according to claim 1 or 2, wherein a waveguide for reflecting radiation is attached to a portion of the inner transparent plate other than the waveguide passage below the horn waveguide.
A housing using solar radiation energy, having the horn waveguide panel according to claim 1 in full or in part on at least one of its side or top surface.

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