KR20110013605A - Vertical bling for windows - Google Patents

Abstract

PURPOSE: A vertical blind is provided to remarkably improve the electric energy generation efficiency of a solar cell module by efficiently receiving sunlight and to track the direction of irradiated sunlight using the solar cell module. CONSTITUTION: A vertical blind comprises a blind(10), solar tracking sensors, a driving unit, and a control unit. The blind is composed of sunshade blades and solar cell modules. The sunshade blades are rotatably coupled to the bottom of a fixing bar(3). The sunshade blades are arranged at uniform intervals and block direct light. The solar cell modules are formed on the front surfaces of the sunshade blades and are rotated with the sunshade blades. The solar cell modules receive solar energy and convert the solar energy into electric energy. The solar tracking sensors are formed on the front surfaces of the solar cell modules. The driving unit rotates the sunshade blades by receiving power. The control unit controls the driving unit depending on signals outputted from the solar tracking sensors.

Description

Vertical blinds {VERTICAL BLING FOR WINDOWS}

The present invention is arranged on the lower portion of the fixed bar is installed on the upper side of the window in the state coupled to the left and right axially coupled to the sunshade wings to block direct sunlight, and the sunshade wing is provided on the front of the sunshade wing Blinds composed of a solar cell module configured to rotate left and right and convert solar energy into electrical energy; A solar tracking sensor provided on the front side of the solar cell module of the blind to detect the irradiation direction of sunlight; A drive unit which receives the power so that the sunshade wing of the blind faces the irradiation direction of sunlight and rotates the sunshade wing to the left and right; And a control unit for controlling the driving unit according to a signal output from the solar tracking sensor.

In general, blinds are used to block external direct sunlight, and are installed and used in a window mounted indoors. Recently, the blinds are beautiful in appearance and have vertical solar cells having a solar cell module that converts solar energy into electrical energy. Blinds have been proposed.

On the other hand, the vertical blind is usually fixed in a direction facing in one direction, whereby the solar cell module is also fixed in a direction along the vertical blind in one direction.

The light receiving efficiency of the solar cell module is increased when the sun is located in the direction of the vertical blind, but the number of the solar cell modules when the sun is not located in the direction of the vertical blind because the sun moves from east to west. Light efficiency as well as electrical energy generation efficiency is also a problem that is lowered.

The present invention was created in order to solve the above-described problems, even if the sun moves over time, the sunshade blades of the blinds rotate left and right according to the movement of the sun, so that the solar cell module of the blinds is irradiated with sunlight. Since the solar cell module can receive sunlight at a higher efficiency because it can be tracked, the efficiency of generating electrical energy of the solar cell module can also be greatly improved, and further, the blinds can be exposed to direct sunlight. It is an object of the present invention to provide a vertical blind that can be easily blocked as well as to view the external landscape through the gap formed between the sunshade wing of the blind.

The present invention for achieving the above object is the sunshade wings arranged at regular intervals in a state in which the upper portion is coupled to the left and right rotatable axially coupled to the lower portion of the fixed bar installed on the upper side of the window, and the sunshade wing A blind provided on the front surface and configured to rotate left and right along the awning wing and configured to convert solar energy into electrical energy; A solar tracking sensor provided on the front side of the solar cell module of the blind to detect the irradiation direction of sunlight; A drive unit which receives the power so that the sunshade wing of the blind faces the irradiation direction of sunlight and rotates the sunshade wing to the left and right; And a controller for controlling the driving unit according to the signal output from the solar tracking sensor.

Here, the timer for setting the drive unit time of the drive unit is preferably provided.

And, it is preferable that the ON / OFF switch to supply and cut off the electrical energy to the drive unit.

Furthermore, the solar tracking sensor is provided on the front surface of any one of the shade blades of the blind arranged at a predetermined interval on the bottom of the fixed bar, the control unit is provided on the front surface of any one of the shade blades of the blind The drive unit may be controlled according to a signal output from the solar tracking sensor to rotate both of the sunshade wings of the blind to the left and right so that all of the sunshade wings of the blind face the irradiation direction of sunlight.

In addition, the solar tracking sensor is provided on the front surface of the solar cell module of the blind, the body is formed on one side and the other inclined surface is inclined downward toward the outer side from the upper side to both sides of the upper surface in a horizontal state; And an optical sensor provided on each of the upper surface, one side, and the other inclined surface of the body to detect an irradiation direction of sunlight and output a signal detected by the controller.

In addition, the control unit preferably compares the output values of the optical sensor provided on the top and one side and the other inclined surface of the body, respectively, and controls the rotational direction of the blind by driving the drive unit according to the comparison result.

According to the present invention, the control unit controls the driving unit according to the signal output from the solar tracking sensor for detecting the irradiation direction of sunlight to rotate the sunshade wing of the blind left and right so that the sunshade wing of the blind toward the irradiation direction of sunlight. Even though the sun moves as the elapse of time, the sunshade wing of the blind rotates left and right according to the movement of the sun so that the solar cell module of the blind can track the irradiation direction of the solar light, so that the solar cell module of the blind has higher efficiency. The solar light can be received as well as the electrical energy generation efficiency of the solar cell module can be greatly improved, and furthermore can block the direct sunlight more easily due to the blind, as well as the shade blade of the blind When turning left and right between the sunshade wing of the blind Through the gaps that are generated it has the effect that the external scenery also allows views.

And, by providing a timer for setting the drive unit time of the drive unit, the drive unit is driven by the control of the control unit for each drive unit time set in the timer so that the blind blades of the blind toward the solar irradiation direction. The sunshade of the left and right to rotate, thereby the solar tracking sensor has the effect of being able to detect the irradiation direction of sunlight per unit time.

In addition, when the ON / OFF switch is set to the ON state, since the control unit controls the drive unit according to the signal output from the solar tracking sensor, the sunshade wing of the blind automatically rotates left and right to face the solar irradiation direction. When the ON / OFF switch is set to the OFF state, the user can manually rotate the shade blades of the blinds manually left and right as needed so that the shade blades of the blinds can face the solar irradiation direction. It works.

Further, when the solar tracking sensor is provided on the front of any one of the sunshade wing of the blind arranged at a predetermined interval on the lower portion of the fixed bar by the control of the control unit through the one of the solar tracking sensor Can easily rotate both the sunshade wings of the blinds, as well as, in particular, the cost of purchasing the solar tracking sensor can be greatly reduced.

In addition, since the optical sensor of the solar tracking sensor is provided on one side and the other inclined surface formed to be inclined downward to the outside on both the upper surface of the body and the upper surface of the body in a horizontal state, the optical sensor of the solar tracking sensor There is an effect that can more easily detect the irradiation direction of sunlight.

Furthermore, the control unit compares the output values of the optical sensors respectively provided on one side and the other inclined surface of the upper surface of the body and then drives the driving unit according to the comparison result to control the rotation direction of the sunshade blade of the blind. The sunshade of the blind has an effect that can more easily track the irradiation direction of sunlight.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

1 is a partial perspective view schematically showing a vertical blind which is an embodiment of the present invention.

Vertical blinds according to an embodiment of the present invention, as shown in Figure 1, comprises a blind 10, a solar tracking sensor, a driver and a control unit.

FIG. 2 is a cross-sectional view schematically illustrating a cross-sectional state of the blind along the line AA of FIG. 1.

First, the blind 10 is to block the direct light, as shown in Figures 1 and 2 largely fixed bar (3) installed horizontally in the upper direction of the rear of the window (not shown) to be located in the interior space A sunshade wing 110 vertically arranged at a predetermined interval in a horizontal direction in a state in which an upper portion is rotatably coupled in a lower portion of the lower portion of the sunshade; It is provided on the front of the awning wing 110 is rotated left and right along the awning wing 110, and known solar cell module 130 for receiving the solar energy to convert into electrical energy; consists of.

As the solar cell module 130, an organic, dye, silicon amorphous thin film solar cell, CIGS solar cell, wafer solar cell, or the like may be used, but is not limited thereto.

However, preferably, as the solar cell module 130, even if a shadow is generated in the solar cell module 130 due to the sun, compared to other solar cells, there is an advantage that the effect of the shadow in terms of efficiency and power is insignificant organic dyes It is better to use solar cells.

The sunshade wing 110 of the blind 10 may be made of a fabric material, etc. Preferably, the high heat generated in the sunshade wing 110 during the process of irradiating sunlight to the solar cell module 130 The sunshade wing 110 is particularly preferably made of aluminum or the like so that it can be radiated to the outside smoothly.

Next, the solar tracking sensor 30 is to detect the irradiation direction of sunlight, is provided on the front of the solar cell module 130 of the blind 10. (See Fig. 5)

3 is a block diagram schematically illustrating a control state of the controller 70.

Next, the driving unit 50 is supplied with power so that the sunshade wing 110 of the blind 10 faces the irradiation direction of sunlight, and rotates the sunshade wing 110 sideways, which is not shown in FIG. 1. However, the driving unit 50 is provided at regular intervals vertically on the upper portion of the fixing bar 3 in the state coupled to the upper portion of the sunshade wing 110 of the blind 10, respectively, the blind 10 The sunshade wing 110 may rotate the sunshade wing 110 to the left and right so as to face the irradiation direction of sunlight.

As the driving unit 50, a motor or the like may be used, but the present invention is not necessarily limited thereto, and any one may be used as long as the sunshade wing 110 may be rotated left and right.

Next, as shown in FIG. 3, the controller 70 controls the driving unit 50 according to a signal output from the solar tracking sensor 30, and is located at a distance adjacent to the blind 10. In addition, the driving unit 50 may be controlled by supplying electrical energy to the driving unit 50 from the storage battery 90 in which the electrical energy converted by the solar cell module 130 is stored.

Although not shown in the drawing, a lower portion of the sunshade wing 110 may be provided with a line such as a wire electrically connected to one side of the solar cell module 130 and the other side to the storage battery 90. In this case, electrical energy converted by the solar cell module 130 may be stored in the storage battery 90 through the line such as a wire.

Next, as shown in FIG. 3, a timer 100 for setting a driving unit time of the driving unit 50 may be provided.

For example, the timer 100 may be provided on the controller 70 in a push button, a dial button, or the like.

Since the timer 100 is configured to set the driving unit time of the driving unit 50, the driving unit 50 is driven by the control of the control unit 70 at every driving unit time set in the timer 100. The sunshade wing 110 of the blind 10 rotates the sunshade wing 110 of the blind 10 to the sun irradiation direction, which causes the solar tracking sensor 30 to sun the unit time There is an advantage to be able to detect the irradiation direction of the light.

Next, as shown in FIG. 3, it is preferable that an ON / OFF switch 150 is provided to supply and cut off electrical energy to the driving unit 50.

When the ON / OFF switch 150 is set to the ON state, the control unit 70 supplies the electric energy stored in the storage battery 90 to the driving unit 50, and the ON / OFF switch 150. In the OFF state, the control unit 70 cuts off electrical energy supplied to the driving unit 50.

That is, when the ON / OFF switch 150 is set to the ON state, the controller 70 supplies electrical energy from the storage battery 90 to the driving unit 50 and outputs from the solar tracking sensor 30. Since the driving unit 50 is controlled according to the signal, the sunshade wing 110 of the blind 10 is automatically rotated left and right to face the solar irradiation direction, and the ON / OFF switch 150 is turned off. When set to the state, the user can manually rotate the sunshade wing 110 of the blind 10 manually left and right as needed so that the sunshade wing 110 of the blind 10 can face the solar irradiation direction. There is an advantage to this.

4 is a longitudinal sectional view schematically showing the driving unit 50.

Next, the solar tracking sensor 30 is provided on the front surface of any one of the sunshade wing 110 of the blind 10 arranged at a predetermined interval below the fixed bar (3), the control unit 70 ) Is the shade of the blind 10 by controlling the drive unit 50 in accordance with the signal output from the solar tracking sensor 30 provided on any one of the shade wing 110 of the blind (10). It is preferable to rotate both of the sunshade blades 110 of the blind 10 so that all of the wings 110 face the irradiation direction of sunlight.

More specifically, the drive unit 50 includes a drive motor 510 in which the drive shaft 511 is horizontally coupled to one side of the fixed bar 3 as shown in FIG. 4; When the drive shaft 511 is reversely rotated by being horizontally provided inside the fixed bar (3) in the state coupled to the drive shaft 511 of the drive motor 510, the control of the controller 70 A rotating shaft 530 which rotates forward and backward along the driving shaft 511; An upper bevel gear 550 coupled to the outer circumference of the rotation shaft 530 at regular intervals to be rotated forward and backward along the rotation shaft 530; It is coupled to the upper bevel gear 550 in the state coupled to the vertical axis 111 formed in the upper portion of the sunshade wing 110 is engaged with each other is provided at a predetermined interval inside the fixed bar (3) And a lower bevel gear 570 for forward and reverse rotation of the sunshade wing 110 by forward and reverse rotation along the upper bevel gear 550.

As shown in FIG. 4, when the drive shaft 511 of one of the driving motors 50 rotates forward and backward under the control of the controller 70, all of the sunshade wings 110 also rotate forward and backward.

The driving unit 50 is not necessarily composed of the driving motor 510, the rotation shaft 530, the upper bevel gear 550, and the lower bevel gear 570, and may reversely rotate all of the sunshade wings 110. If there is a composition, it is enough.

One solar tracking sensor when the solar tracking sensor 30 is provided on the front surface of any one of the sunshade wing 110 of the blind 10 arranged at a predetermined interval below the fixed bar (3). Under the control of the control unit 70 through the 30, the driving unit 50 can easily rotate left and right all of the sunshade wing 110 of the blind 10, in particular, the solar tracking sensor There is an advantage that the purchase cost and the like of 30 can be greatly reduced.

5 is a perspective view schematically illustrating the solar tracking sensor 30, and FIG. 6 is a plan view schematically illustrating a state in which the solar tracking sensor 30 of FIG. 5 is provided in the solar cell module 130.

Next, the solar tracking sensor 30 is large, as shown in Figure 5 and 6, provided on the front of the solar cell module 130 of the blind 10, both sides of the upper surface 311 in a horizontal state A body 310 in which one side and the other inclined surfaces 313 and 315 are inclined downward from the upper side to the lower side; Signals detected by the controller 70 by detecting the irradiation direction of the sunlight (see dotted arrows in FIG. 6) provided on the upper surface 311 and the one side and the other inclined surfaces 313 and 315 of the body 310, respectively. It is preferable that the optical sensor 330 to output the.

In order to prevent the optical sensor 330 from being damaged by an external force or the like, the optical sensor has an upper surface 311 and one side and the other inclined surfaces 313 and 315 of the body 310 as shown in FIGS. 5 and 6. It is preferable to be provided in the upper portion of the body 310 to be located in the lower direction, wherein the upper surface 311 and one side and the other inclined surface (313, 315) of the body 310 is made of a transparent material such as tempered glass Can be.

As the optical sensor 330, a known photodiode (a type of semiconductor diode, which is used to detect light by using a property of generating current when light hits a semiconductor junction) may be used. However, it is not necessarily limited thereto.

The one side and the other side of which the optical sensor 330 of the solar tracking sensor 30 is inclined outwardly downward on both sides of the upper surface 311 of the body 310 and the upper surface of the body 310 in a horizontal state. Since the inclined surfaces 313 and 315 are respectively provided, the optical sensor 330 of the solar tracking sensor 30 can more easily detect the irradiation direction of sunlight.

7 to 9 are plan views schematically showing a state in which the blind 10 is rotated left and right to track the sun.

Next, the control unit 70 compares the output values of the optical sensor 330 respectively provided on the upper surface 311 of the body 310 and the one side and the other inclined surfaces 313 and 315, respectively, in the comparison result. Accordingly, the driving unit 50 may be driven to control the rotation direction of the blind 10.

First, for convenience of description, the optical sensors 330 provided on the upper surface 311 and one side and the other inclined surfaces 313 and 315 of the body 310 may be provided with the first, second, and third light sensors 331, 333, 335).

Photovoltaic light receiving efficiencies of the first, second and third light sensors 331, 333, and 335 according to the movement of the sun 5 moving from east to west are different from each other.

For example, as shown in FIG. 6, when the sun 5 is positioned in the direction in which the second optical sensor 333 faces, the solar light receiving efficiency of the second optical sensor 333 is the first and third. The light receiving efficiency of the photosensors 331 and 335 is higher.

More specifically, the output value of the second light sensor 333 among the first, second and third light sensors 331, 333, 335 is greater than the output value of the first, third light sensors 331, 335. In other words, when the sun 5 is positioned in the direction in which the second optical sensor 333 faces (see FIG. 6), as shown in FIG. 7, the sunshade wing 110 of the blind 10 is left. In order to be inclined in the diagonal (/) direction by the control of the control unit 70, the drive unit 50 is to rotate the sunshade wing 110 of the blind 10 to the left.

The output value of the first, second, and third light sensors 331, 333, and 335 output by the first light sensor 331 is greater than that of the second, third, or third light sensors 333, 335. When the sun 5 is located in the direction in which the first optical sensor 331 faces (see FIG. 6), as shown in FIG. 8, the driving unit 50 is controlled by the control unit 70. 10, the sunshade wing 110 is rotated left and right so that the sunshade wing 110 of the blind 10 inclined obliquely to the left to achieve a horizontal state.

When the output value of the first, second, and third light sensors 331, 333, and 335 is output by the third light sensor 335 is greater than the output value of the first, second, or third light sensors 331, 333. When the sun 5 is positioned in the direction in which the third optical sensor 335 faces (see FIG. 6), as shown in FIG. 9, the sunshade wing 110 of the blind 10 is oblique to the right. The driving unit 50 rotates the sunshade wing 110 of the blind 10 in a horizontal state to the right by the control of the control unit 70 so as to be inclined in the direction.

As described above, the controller 70 compares the output values of the optical sensors 330 provided on the upper surface 311 and the one side and the other inclined surfaces 313 and 315 of the body 310, respectively, and then compares them. As the result of driving the driving unit 50 to control the rotation direction of the sunshade wing 110 of the blind 10, the sunshade wing 110 of the blind 10 more easily in the direction of irradiation of sunlight ( 6) the advantage of being able to track.

According to the present invention configured as described above, the control unit 70 controls the driving unit 50 according to the signal output from the solar tracking sensor 30 for detecting the irradiation direction of sunlight to shade of the blind 10. Since the wing 110 rotates the sunshade wing 110 of the blind 10 to face the irradiation direction of sunlight, even if the sun moves over time, the sun shade of the blind 10 moves as the sun moves. The wing 110 is rotated left and right so that the solar cell module 130 of the blind 10 can track the solar irradiation direction, so that the solar cell module 130 of the blind 10 has higher efficiency. Of course, it is possible to receive light, and thus the electrical energy generation efficiency of the solar cell module 130 may also be greatly improved.

For example, the efficiency difference of up to 25 Wp (about 30 to 50%) may occur when the 50 Wp (unit output power) solar cell module 130 does not track the solar irradiation direction.

In addition, the present invention configured as described above can block the direct sunlight more easily due to the blind 10, as well as the shade of the blind 10 when the sunshade wing 110 of the blind 10 is rotated left and right. Through the gap (7 of FIG. 1) formed between the wings 110 there is an advantage that the view of the outside can also be viewed.

1 is a partial perspective view schematically showing a vertical blind which is an embodiment of the present invention,

2 is a plan sectional view schematically showing the cross-sectional state of the blinds,

3 is a block diagram schematically illustrating a control state of a controller;

4 is a longitudinal sectional view schematically showing a driving unit;

5 is a perspective view schematically showing a solar tracking sensor,

6 is a plan view schematically showing a state in which the solar tracking sensor of FIG. 4 is provided in the solar cell module;

7 to 9 are schematic plan views of a state in which the blind is rotated left and right to track the sun.

*** Explanation of symbols for main parts of drawing ***

3; Fixed bar, 5; Sun,

7; Niche, 10; blind,

110; Sunshade wing, 111; Vertical Axis,

130; Solar cell module, 150; ON / OFF switch,

30; Solar tracking sensor, 310; Body Part,

311; Upper surface, 313; One Side Slope,

315; The other inclined plane, 330; Optical Sensor,

331, 333, 335; First, second and third optical sensors 50; Driver,

530; Axis of rotation, 550; Upper bevel gear,

570; Lower bevel gear, 70; Control,

90; Storage batteries, 100; timer.

Claims (6)

A sunshade wing arranged at a predetermined interval in a state in which the upper part is axially coupled to the lower portion of the fixed bar installed on the upper side of the window to block direct sunlight, and is provided on the front of the sunshade wing to rotate left and right along the sunshade wing. And blind comprising a solar cell module for converting solar energy into electrical energy; A solar tracking sensor provided on the front side of the solar cell module of the blind to detect the irradiation direction of sunlight; A drive unit for rotating the sunshade blades left and right so that the sunshade wing of the blind faces the irradiation direction of sunlight; And a control unit controlling the driving unit according to the signal output from the solar tracking sensor. The method of claim 1, Vertical blinds, characterized in that provided with a timer for setting the drive unit time of the drive unit. The method of claim 1, Vertical blinds characterized in that the ON / OFF switch for supplying and cutting off the electrical energy to the drive unit. The method of claim 1, The solar tracking sensor is provided on the front of any one of the sunshade wings of the blind arranged at a predetermined interval on the lower portion of the fixed bar, The control unit controls the drive unit according to a signal output from the solar tracking sensor provided on the front surface of any one of the sunshade wings of the blind so that all of the sunshade wings of the blind toward the irradiation direction of sunlight. Vertical blinds, characterized by rotating both wings. The method of claim 1, The solar tracking sensor is provided on the front surface of the solar cell module of the blind, and the body is formed on one side and the other inclined surface inclined downward toward the outer side from the upper side to both sides of the upper surface in a horizontal state; Vertical blinds provided on each of the upper surface and one side and the other inclined surface of the body to detect the irradiation direction of sunlight and output the signal detected by the control unit. The method of claim 5, The control unit compares the output value of the optical sensor, respectively provided on one side and the other inclined surface of the upper surface of the body and then drive the drive unit in accordance with the comparison result, characterized in that the vertical blinds control the rotation direction of the blinds .

Images