KR101256638B1 - Solar photovoltaic blind - Google Patents

Abstract

It relates to a solar power blind that can serve as a solar power generation function as well as sunshade. The solar power blind includes a screen, a battery, a driving mechanism, and a control unit. The screen has a flexible solar cell positioned indoors to face the glass window. Storage batteries are for collecting electricity obtained from solar cells. The drive mechanism causes the screen to be rolled up or unwound in a rolled form. The control unit controls the storage battery and the drive mechanism.

Description

Solar photovoltaic blinds {Solar photovoltaic blind}

The present invention relates to blinds, and more particularly, to a photovoltaic blind that can serve as a solar power generation function.

In general, the blind is installed on the glass window in the interior of the building, and prevents sunlight from entering the interior, and serves to prevent the indoor situation from being exposed to the outside. By the way, the conventional blinds mostly provide a role of simply blocking the sunlight or simply blocking the indoor situation.

In addition, when the entire window is covered by blinds and the sun is blocked, artificial lighting such as a lamp must be turned on to brighten the room because the room is dark. However, since electricity must be used to turn on artificial lighting, electric energy is consumed a lot. In recent years, energy-saving eco-friendly buildings are in the spotlight, and in order to construct such buildings, efforts are needed to reduce the consumption of electric energy.

An object of the present invention is to provide a solar power blind that can be equipped with a power generation function as well as a sunshade function, which can reduce energy consumption due to the use of electric energy and can help to operate an energy-saving eco-friendly building.

According to an aspect of the present invention, there is provided a solar power blind comprising: a screen having a flexible solar cell positioned to face a glass window in a room; A storage battery for collecting electricity obtained from the solar cell; A drive mechanism for unwinding the screen in a roll form or in a rolled state; And a control unit for controlling the storage battery and the driving mechanism.

According to the present invention, the screen is draped on the glass window at the time of the direct sunlight to block the sunlight coming through the glass window and at the same time can generate electricity by the solar cell. The electricity generated by the solar cell can be supplied to and used for the driving mechanism for driving the screen through the storage battery. The surplus electricity of the battery can be supplied and used for indoor lighting of the building, thereby reducing the consumption of electrical energy in the building. Therefore, it can be effective to contribute to the operation of energy-saving eco-friendly buildings.

In addition, according to the present invention, since the screen is wound so that the light can be lighted when the amount of light entering through the glass window is small, it can be aesthetically pleasing and can have the effect of not harming the aesthetics when viewing a building from the outside.

1 is a side view of a solar power blind according to an embodiment of the present invention.
2 is a perspective view of FIG. 1.
3 is a perspective view showing a state in which the screen is wound in FIG.
4 is a front view of FIG. 1.
FIG. 5 is a side view of the unrolled surface of the screen inclined in FIG. 1; FIG.
FIG. 6 is a side view of the example of FIG. 5 in which the unwinded side of the screen is configured to adjust the tilted angle; FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a side view of a photovoltaic blind according to an embodiment of the present invention. 2 is a perspective view of FIG. 1. FIG. 3 is a perspective view illustrating a wound state of the screen in FIG. 2. 4 is a front view of FIG. 1.

1 to 4, the photovoltaic blind 100 includes a screen 110, a storage battery 120, a drive mechanism 130, and a controller 140.

Screen 110 has a solar cell 111. The solar cell 111 is a device which converts light energy into electrical energy using a P-type semiconductor and an N-type semiconductor. The solar cell 111 is positioned to face the glass window 10 indoors.

The solar cell 111 is made flexible. Therefore, the solar cell 111 may be wound or unwound in a roll form. The solar cell 111 generates electric energy by receiving sunlight incident through the glass window 10 in a state unfolded toward the glass window 10 and may block sunlight coming through the glass window 10. .

The solar cell 111 may have a square shape in a fully unfolded state and may have a size capable of covering the glass window 10 as much as possible. Therefore, the solar cell 111 can obtain the maximum electrical energy in the fully unfolded state, and can also obtain the maximum shading effect. The solar cell 111 may be arranged in the form of a plurality of panels and connected in series and in parallel.

The storage battery 120 is for collecting electricity obtained from the solar cell 111. The storage battery 120 is electrically connected to the solar cell 111. The storage battery 120 receives the electricity obtained from the solar cell 111 and changes it into chemical energy and accumulates it. In addition, the storage battery 120 converts the stored chemical energy into electrical energy so that the power source can be provided where necessary.

The drive mechanism 130 causes the screen 110 to be rolled up or unwound in a rolled state. The drive mechanism 130 operates to wind the screen 110 when light is required, and to unwind the screen 110 when light and power generation are needed.

The controller 140 controls the driving mechanism 130 to allow the screen 110 to be wound or unwound by the driving mechanism 130. In addition, the controller 140 controls the storage battery 120. For example, if electricity is accumulated in the storage battery 120 from the solar cell 111, the control unit 140 supplies the accumulated electricity to the driving mechanism 130 or the surplus periodicity of the storage battery 120 to the indoor lighting. The storage battery 120 may be controlled to be supplied.

As described above, the photovoltaic blind 100 is a solar cell 111 at the same time blocking the sunlight coming through the glass window 10, the screen 110 is cast on the glass window 10 in the time of direct sunlight. Can generate electricity. The electricity generated by the solar cell 111 may be supplied and used to the driving mechanism 130 for driving the screen 110 through the storage battery 120. In addition, since the surplus electricity of the storage battery 120 can be supplied and used to the indoor lighting of the building, it is possible to reduce the consumption of electrical energy in the building. Therefore, it can contribute to operating an energy-saving eco-friendly building.

And, since the screen 110 is wound so that light can be mined when the amount of light entering through the glass window 10 is small, the photovoltaic blind 100 can be aesthetically pleasing and aesthetically pleasing when looking at a building from the outside. Can not hurt.

Meanwhile, the screen 110 may include the sun visor member 112. The sunshade member 112 is attached to the rear surface of the solar cell 111, that is, the surface facing the room of the both sides of the solar cell 111. Shading member 112 is made of a flexible, light-shielding material that can block the sun. For example, the shading member 112 may be made of a material such as a light shielding cloth.

Therefore, the sunshade member 112 may increase the effect of blocking the sunlight incident through the glass window 10 together with the solar cell 111 in the unwinded state. In addition, when the solar cell 111 is wound or unwound in a roll form, the sunshade member 112 may be wound or unwound in a roll form together with the solar cell 111.

The sunshade member 112 may have a square shape in a fully unfolded state and may have a size that can cover the glass window 10 as much as possible. If there is an edge region in which the solar cell 111 is not disposed on the front surface of the shade member 112, a film having the same thickness as the solar cell 111 may be attached to the edge region. Therefore, when the solar cell 111 is wound together with the sunshade member 112, the pressure applied to the solar cell 111 can be reduced.

The drive mechanism 130 may be installed to wind up or unwind the screen 110 from the top of the screen 110. In this case, the load bar 113 may be installed at the bottom of the screen 110. The load bar 113 allows the screen 110 to be rolled up or unrolled while remaining flat.

The drive mechanism 130 may be configured in various ways. For example, the driving mechanism 130 may include a shaft 131, a driving wheel 132, and a motor 133. The shaft 131 is rotatably supported and winds the screen 110 around its outer circumference. The shaft 131 has a structure in which both ends are open and have a hollow. The upper end of the screen 110 may be positioned in the longitudinal direction of the shaft 131 and may be fixed to an outer surface of the shaft 131. The drive wheel 132 is coupled to the hollow of the shaft 131 and rotates with the shaft 131.

The motor 133 drives the driving wheel 132 to rotate. The motor 133 rotates the drive wheel 132 in the forward or reverse direction to rotate the shaft 131 in the forward or reverse direction, so that the screen 110 is wound around the shaft 131 or from the shaft 131. Let loose.

The motor 133 may be a cylindrical motor. The cylindrical motor has a cylindrical motor body. The motor head is located at one end of the motor body, and the motor shaft is drawn out at the other end of the motor body.

The motor body is fitted through one opening of the shaft 131. The motor rotation shaft is located inside the shaft 131 and is coupled to the driving wheel 132. The motor head is located outside the shaft 131 and mounted to the motor bracket 134. The motor bracket 134 may be mounted to the upper frame 20 installed at the upper side of the glass window 10 in the room. The end plug 135 may be fitted into the other opening of the shaft 131. The end plug 135 has a shaft formed on an outer surface thereof, and the shaft can be rotatably supported by being fitted to the shaft support bracket 136. Therefore, both sides of the shaft 131 can be rotatably supported.

Screen guides 150 may be provided at both sides of the screen 110. The screen guide 150 guides the winding or unwinding of the screen 110 on both sides of the screen 110. The screen guide 150 may be configured in various ways. For example, the screen guide 150 may include a wire 151 and a turnbuckle 152 in pairs.

Turnbuckle 152 is for pulling wire 151 in place. Turnbuckle 152 has male threaded rods that are screwed to both sides of the buckle body. Here, the right hand thread is formed in one male threaded rod, and the left hand thread is formed in the other male threaded rod. Rotating the buckle body causes the male rods to approach or move away from each other depending on the direction of rotation of the body. Operating the buckle body to bring the male threaded rods close to each other can cause the wire to be pulled and tightened.

The wires 151 are arranged to guide the winding or unwinding of the screen 110 to the left and right of the screen 110. One end of each wire 151 is coupled to a lower frame 30 installed below the windowpane 10 indoors, and the other end of each wire 151 is connected to one of the male threaded rods of the turnbuckle 152. Combined. The other of the male threaded rods of the turnbuckle 152 is coupled to the upper frame 20. In addition, the wires 151 may be fitted into guide holes formed at both ends of the load bar 113 to guide the winding or unwinding of the screen 110. Meanwhile, the screen guide 150 may be configured to include rails for guiding the winding or unwinding of the screen 110, but is not limited thereto.

The controller 140 may automatically control the screen 110 according to the light quantity information coming into the glass window 10. To this end, the illumination sensor 161 may be provided. The illuminance sensor 161 is installed to detect the amount of light incident on the screen 110. If the controller 140 receives a signal output from the illuminance sensor 161 and determines that the amount of light is less than the set light amount, the controller 140 controls to reduce the amount of electricity used for indoor lighting, and raises the screen 110 to light the driving mechanism 130. Can be controlled.

In addition, the controller 140 may automatically control the screen 110 according to whether or not there is a person in the room. To this end, a motion detector 162 may be provided. The motion detector 162 is installed to detect the presence of a person indoors. When the controller 140 receives a signal output from the motion detector 162 and determines that there is no person in the room for a predetermined time or more, the controller 140 controls to turn off the indoor lighting, and controls the driving mechanism 130 to lower the screen 110 to block the light. Can be controlled. In the state where the screen 110 is lowered, electricity can be obtained by the solar cell 111.

As shown in FIG. 5, the screen 110 may be installed such that the unrolled surface is parallel to the vertical plane in a fully unrolled state, but may be installed so that the unrolled surface is inclined with respect to the vertical plane. In this case, the angle at which the loosened surface of the screen 110 is inclined may be set to allow the solar cell 111 to receive sunlight optimally. In this case, the wires 151 of the screen guide 150 may be inclined at both sides of the screen 110 so that the unwinded surface of the screen 110 is inclined with respect to the vertical surface.

As shown in FIG. 6, in a state in which the screen 110 is completely unwound, an angle adjusting mechanism 170 may be provided to adjust an angle at which the unwinded surface of the screen 110 is inclined with respect to the vertical plane. The angle adjusting mechanism 170 may include a guide rail 171, a moving block 172, and a linear actuator 173.

The guide rail 171 guides the motor bracket 134 and the shaft support bracket 136 to slide horizontally with respect to the upper frame 20 so that the drive mechanism 130 can be moved horizontally. The moving block 172 is connected to the motor bracket 134 and the shaft support bracket 136. The linear actuator 173 allows the drive mechanism 130 to move forward or backward by moving the moving block 172 forward or backward. As the linear actuator 173, a cylinder or the like may be used.

As the driving mechanism 130 moves forward or backward by the aforementioned angle adjusting mechanism 170, the inclination angle of the unwinded surface of the screen 110 may be adjusted. As another example, the angle adjustment mechanism 170 may be installed on the lower frame 30 to advance or reverse the lower ends of the wires 151 to adjust the inclination angle of the unwinded surface of the screen 110.

When the inclination angle of the loosened surface of the screen 110 is adjusted, the wires 151 of the screen guide 150 need to be adjusted in length. To this end, the screen guide 150 may include a wire length adjuster 153 instead of the turnbuckle 152. The wire length adjusting unit 153 may include a roller for winding the wire 151 and an elastic member for applying an elastic force to pull the wire 151. The wire length adjusting unit 153 moves together with the motor bracket 134 and the shaft support bracket 136.

On the other hand, the angle adjustment mechanism 170 may be controlled by the controller 140 according to the sun altitude. To this end, the solar altitude meter 163 may be provided. Solar altitude meter 163 is installed to measure the solar altitude. The controller 140 may control the angle adjusting mechanism 170 to receive the signal output from the sun altitude measuring instrument 163 and adjust the inclination angle of the unwinded surface of the screen 110 according to the sun altitude. Therefore, electricity can be optimally obtained by the solar cell 111.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

110. Screen 111. Solar cell
112. Shading member 120. Storage battery
130. Drive mechanism 140. Control unit
150. Screen guide 170. Angle adjustment mechanism

Claims (8)

A screen having a flexible solar cell positioned to face a glass window indoors and a load bar installed at the bottom;
A storage battery for collecting electricity obtained from the solar cell;
A drive mechanism for winding the screen in a roll form or unwinding from the top of the screen; And
A guide rail for adjusting an inclined angle of the unwinding surface of the screen with respect to a vertical surface, and formed on an upper frame installed at an upper side of the glass window to guide the driving mechanism to slide horizontally in the front-rear direction of the glass window; An angle adjusting mechanism having a linear actuator for moving the driving mechanism forward or backward;
Screen guides each guiding winding or unwinding of the screen on both sides of the screen; And
A control unit for controlling the storage battery, the drive mechanism, and the linear actuator;
PV blinds comprising a. The method of claim 1,
And said screen includes a flexible sunshade member attached to the interior facing surface of said solar cell. delete The method of claim 1,
The drive mechanism includes:
A shaft rotatably supported and winding the screen around its outer periphery,
A driving wheel coupled to the hollow of the shaft and rotating together with the shaft, and
And a motor for rotating the drive wheel. delete delete The method of claim 1,
A sun altitude meter for measuring sun altitude;
The control unit,
And an angle adjusting mechanism for controlling the inclination angle of the unrolled surface of the screen according to the solar altitude by receiving a signal output from the solar altitude measuring instrument. The method of claim 1,
An illuminance sensor detecting an amount of light incident on the screen, and a motion detector detecting a presence of a person in the room;
The control unit,
If it is determined that the signal output from the illuminance sensor is less than the set amount of light, the driving mechanism is controlled to reduce the amount of electricity used for indoor lighting while raising the screen to light the light.
And determining that there is no person in the room for more than a predetermined time by receiving the signal output from the motion detector, and controlling the driving mechanism to turn off the screen while shading the screen.

Images