KR20000065915A - Blinder apparatus adapting at sunlight - Google Patents

Abstract

PURPOSE: A sunlight adjustable blinder is provided to automatically control length and angular degrees of a blinder corresponding to angle and intensity of sunlight irradiation. CONSTITUTION: According to the elapse of time, an irradiation angle of sunlight increases. A control unit reads out the data about an opened length and mounted angular degrees of a blinder unit from a data memory(34) to create control signals to first and second motor drive units(30,32). The first motor is rotated right to lift up the blinder unit and the second motor is rotated to wind up a first angular degree control rope upwardly. Thereby, the blind is adjusted corresponding to length and angle of sunlight irradiation.

Description

Solar apparatus adapting at sunlight

The present invention relates to a photovoltaic adaptive blinder device, and more particularly, to allow the light-receiving device to adjust the opening degree of the blinder due to the photocurrent detected from the photosensitive solar sensor consisting of vertical / horizontality and to store the photocurrent applied therefrom. The present invention relates to a photovoltaic adaptive blinder device which can be used as a driving source of a blinder.

In recent years, as the development of science and technology progresses toward a human center, it is possible to more conveniently manipulate instruments or devices without human hands, and in particular, the development of various processors has made this a reality.

In the above-described trend, the curtain is automatically opened when the light is detected in the state that the human hand does not go, and the automatic curtain that is opened and closed by the sun detection that the curtain is automatically closed when the light is not detected is implemented.

The automatic curtain is generally provided with a single light receiving element, and consists of a microcomputer receiving the signal of the light receiving element.

In addition, a driving motor driven by receiving a control signal from the microcomputer is configured, and a plurality of driving motors are provided at both sides of the auto curtain.

Thus, when sunlight is received and a photocurrent is detected through the light receiving element above a predetermined value, the input signal is applied to the side of the microcomputer, and the microcomputer drives the driving motor to open the curtain.

On the other hand, when the photocurrent detected through the light receiving element is detected below the set value, the microcomputer recognizes that it is night and drives the driving motor so that the curtain can be closed.

However, in the case of the automatic curtain described above, when the sunlight irradiated in the summer is detected to be above a predetermined reference value, precise control is difficult when the curtain is to be closed, a problem arises in that the curtain must be manually operated.

In addition, since only a single light receiving element is used to perform the opening and closing operation of the curtain using only light detection, there is a problem that opening and closing of the curtain according to the position of the sun becomes difficult.

In particular, by applying the method of the automatic curtain to the blinder to control the opening and closing of the blinder in consideration of the irradiation amount of sunlight, it also detects a simple amount of irradiation and the technology affects the opening and closing degree of the blinder, precise control and sunlight Accumulation effect of the used power supply becomes impossible.

However, most offices, buildings, and libraries are equipped with blinds, and especially when the number of installations such as blinds in large buildings or library blinds is extremely large, the extension length and angle of the blinds depend on the amount of irradiation and irradiation angle of sunlight. There is a need for an automatic blinder that can be adjusted automatically in response.

An object of the present invention is made in view of the above-described circumstances of the prior art, it detects the irradiation angle and the irradiation amount of the sun according to the season and time, and correspondingly the elongation length and angle of the blinder can be automatically adjusted according to a predetermined value It is an object of the present invention to provide a photovoltaic adaptive blinder device that can be used as a driving source of the blinder by accumulating the generated photocurrent.

In order to achieve the above object, according to the first embodiment of the present invention, the long hole through which the lifting rope passes through the plane so as to block or apply the irradiation of sunlight by spreading over the upper and lower ends of the window, and the angle A blinder comprising a plurality of blinder pieces having a cutout through which a string for adjustment is passed,

A solar light detector configured to be installed on an outer wall of the building to adjust the opening length of the blinder and an installation angle of the blinder to correspond to the irradiation angle of the sun and the amount of sunlight;

A storage battery configured to use the load current by accumulating the photocurrent generated from the solar sensing unit;

A function input unit provided with an automatic / manual mode conversion button for adjusting the opening length of the blinder and an installation angle of the blinder;

A data storage unit in which data of an opening length and an installation angle of the blinder portion corresponding to the irradiation distribution of the sunlight detected from the solar detector and the moon input input from the function input unit are preset;

The irradiation angle of sunlight and the month input inputted from the function input unit are received from the solar sensing unit, and data about the opening length and installation angle of the blinder side are read from the data storage unit to the lifting motor and the angle adjusting motor. There is provided a photovoltaic adaptive blinder device comprising a control unit configured to generate a control signal and drive the lifting drive roller and the angle adjusting roller so that the lifting and lowering operation of the blinder is made.

Preferably, according to the first embodiment of the present invention, the upper surface of the solar sensing unit is configured to be convex so as to detect the irradiation angle of sunlight through the irradiation distribution of sunlight, the light receiving element array is formed on the upper surface in rows and columns do.

More preferably, a worm wheel is formed at one end of each of the rollers so that a worm is coupled to the shaft of each of the motors and engaged with the worm.

Therefore, according to the present invention having the above-described configuration, when the irradiation angle and the brightness of the sun are detected through the solar sensing unit, the detected value is applied to the controller, and the controller is controlled from the data storage unit by the month input input from the function input unit. By reading data about the opening length and the installation angle of the blinder, the elevating motor and the angle adjusting motor are driven to automatically adjust the blinder corresponding to the irradiation angle and light quantity of sunlight.

1 is a perspective view showing a solar adaptive blinder device according to a first embodiment of the present invention,

Figure 2 is a side view showing a solar adaptive blinder device according to a first embodiment of the present invention,

3 is a block diagram showing a circuit configuration of a solar adaptive blinder device according to a first embodiment of the present invention;

4 is a perspective view showing a solar sensing unit of the solar adaptive blinder device according to the first embodiment of the present invention,

5A, 5B, and 5C are diagrams illustrating time-phase change values of photocurrent detected by the solar sensing unit of the solar adaptive blinder device according to the first embodiment of the present invention;

6A and 6B are data diagrams schematically showing seasonal change values of photocurrent detected through the solar sensing unit of the solar adaptive blinder device according to the first embodiment of the present invention.

7 is a perspective view illustrating a state in which the solar adaptive blinder device according to the second embodiment of the present invention is applied to a vertical blinder,

8 is a perspective view showing an angle adjusting unit in the vertical blinder of FIG.

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

2: blinder, 4: lifting rope,

6: lift drive roller, 12: 1st motor,

14: second motor, 16: housing,

18: angle adjusting rope, 20: angle adjusting roller,

26: solar sensing unit, 28: function input unit,

29: illuminance detection unit, 30: the first motor drive unit,

32: second motor drive unit, 33: switching unit,

34: data storage, 35: lighting,

36: control unit, 38: storage battery,

40: horizontal transfer motor, 48: transmission wire,

50a to 50n: flow part housing, 52: fixed protrusion,

56: vertical blinder, 58: extension cord,

64: angle adjusting motor.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail with reference to drawings.

1 is a perspective view showing a solar adaptive blinder device according to a first embodiment of the present invention, Figure 2 is a side view showing a solar adaptive blinder device according to an embodiment of the present invention.

Referring to this, it is located at the lower end of the pieces of the blinder, one side is provided with a blind support (not shown) fixed by the lifting rope 4, the blind support has a constant weight and As the lifting rope 4 is wound and unwound, the blinder piece 2 can be vertically lifted and lowered.

On the other hand, the other side of the elevating rope (4) is fixedly coupled to the elevating drive roller (6) when the elevating drive roller (6) is rotated to perform the elevating and descending operation winding the elevating line (4) Or solve.

In addition, a worm wheel 8 is formed on one side of the elevating driving roller 6, and a worm 10 is formed to be engaged with the worm wheel 8 at a predetermined angle, and the worm 10 is formed. ) Is coupled to the axis of the first motor 12.

In particular, a worm gear formed of the worm 10 and the worm wheel 8 is formed between the lifting driving roller 6 and the first motor 12 so that the first motor 12 is driven so that the blinder piece ( After 2) has risen to a constant height, the voltage applied to the first motor 12 is lost, and the blinder piece 2 is lowered due to the load of the blinder support provided at the lower portion of the blinder piece 2. In order to prevent that, the blinder piece 2 is provided to have a reduction ratio such that it does not lower.

On the other hand, the first motor 12 is wound and pulled the blinder piece 2 by using a forward and reverse motor capable of rotating in the forward and reverse directions, and a motor having a function of a step motor whose rotation speed changes according to the applied pulse value. It is possible to adjust the installation length of the blinder piece 2 according to the applied pulse value.

In this case, a power source for driving the first motor 12 and the second motor 14 may be a commercial power source, or may be driven using a solar power source.

And, the shaft 6a is formed to protrude on both sides of the elevating drive roller 6, the protruding shaft 6a is the side of the housing 16 including the elevating drive roller 6 therein It is inserted into the groove and rotated.

In addition, the blind piece 2 has a long hole (2a) is formed so that the lifting rope (4) can be inserted, through the long hole (2a) the lifting rope (4) is a plurality of blind pieces ( Passed through 2) is coupled to the blinder support (not shown) provided at the bottom of the blinder piece (2).

On the other hand, each of the blinder piece (2) has a cutting hole (2b) through which the first angle adjustment line (18a) and the second angle adjustment line (18b) is passed so that the angle adjustment of the blinder piece (2) can be made It is formed, it is connected through each incision hole (2b) of the blinder piece (2) and the first angle adjustment line (18a) and the second angle adjustment line (18b) is a joint line at the lower end of the incision hole (2b) The connection 18c allows the blinder piece 2 to be supported by the seam 18c.

Then, the angle adjusting line (18a, 18b) is wound on the angle adjustment roller 20 once and then connected to the blinder piece (2) to the front / rear relative to the angle adjustment roller 20, the angle adjustment roller When the 20 is rotated, the first and second angle adjustment strings 18a and 18b can be pulled and released.

Meanwhile, a worm wheel 22 is formed at one end of the angle adjusting roller 20, and a worm 24 is formed to mesh with the worm wheel 22, and the worm 24 is a second motor 14. ) Is coupled to the axis.

3 is a block diagram showing a circuit configuration of a solar adaptive blinder device according to a first embodiment of the present invention.

Referring to this, reference numeral 26 denotes a solar sensing unit for sensing an irradiation angle and an irradiation amount of sunlight, and the solar sensing unit 26 is attached to, for example, an outer wall of a building, and a plurality of light receiving elements are arranged on the outer surface thereof. The length and installation angle of the blinder piece 2 can be adjusted through the distribution position and the photocurrent amount of the array in which the photocurrent is generated when receiving the angular light.

At this time, the solar sensing unit 26 is mounted on the four sides of the outer wall of the building when used in large buildings and offices, such as buildings, and detects each of the blinder pieces 2 provided in the window of the building surface attached thereto. It is possible to adjust to correspond to the signal.

Of course, even if a single solar sensing unit 26 is applied to a single building such as a single house, it is possible to sufficiently adjust the blinder piece 2 to correspond to the detection signal.

Further, reference numeral 28 includes an automatic mode for operating the blinder piece 2 by driving the first motor 12 and the second motor 14 and a conversion to a manual mode configured in the same manner as a general blinder. The function input unit 28 is configured with a monthly input button so that the blinder piece 2 can be driven in response to a change in the irradiation angle of the sun from month to month.

Reference numeral 29 denotes an illuminance detecting unit installed in a predetermined part of the room to sense the illuminance of the room, and the illuminance detecting unit 29 turns off the indoor lighting when the amount of illuminance introduced into the room is greater than or equal to a predetermined value. It is composed.

On the other hand, reference numeral 30 denotes a first motor driving unit for driving the first motor 12 to adjust the opening length of the blinder piece (2), 32 is to drive the second motor 14 A second motor driving part for adjusting the installation angle of the blinder piece 2 is shown.

In addition, 33 has a relay switch therein is switched by a predetermined control signal generated by the illuminance sensing unit 29, the switching unit for applying / blocking the power to the lighting unit 35 configured at the rear end thereof Indicates.

34 denotes a data storage unit in which the opening length and installation angle of the blinder piece 2 corresponding to the light distribution and the photocurrent amount of the light receiving element array included in the solar sensing unit 26 are preset. The data storage unit 34 includes an opening length and an installation angle of the blinder piece 2 corresponding to the input value of the monthly input button of the function input unit 28, and a power input / blocking state of the lighting unit 35. The set illuminance data is stored in the form of table memory.

On the other hand, 36 represents a control unit for driving control of the blinder piece 2, the control unit 36 is received from the solar light sensing unit 26 in the automatic mode is set in the function input unit 28 The first motor driver 30 and the first motor are read from the data storage unit 34 by reading the distribution position of the device array and the photocurrent at that time, and reading the opening length and installation angle of the blinder piece 2 corresponding thereto. The first motor 30 and the second motor 32 are driven by generating a control signal to the second motor driver 32 to adjust the opening length and the installation angle of the blinder piece 2.

In addition, the controller 36 receives an optical signal applied from the solar sensing unit 26 and an illuminance value from the illuminance detecting unit 29 configured in the room, and reads the data from the data storage unit 34. By controlling the switching unit 33 by comparing with a predetermined illuminance value, the lighting unit 35 located in the room is controlled on / off.

38 represents a storage battery that receives and stores photocurrent generated from the solar sensing unit 26. Since an AC / DC converter is built in the battery 38, a commercial power is applied from an external side of the storage battery 38. It is also possible to drive the.

4 is a perspective view showing a solar light sensing unit of the solar adaptive blinder device according to the first embodiment of the present invention.

Referring to this, in order to manipulate the length and installation angle of the blinder piece (2), the sunlight sensing unit 26 for detecting sunlight is formed in a convex shape of the upper surface, the lower side of the upper surface is high and When the upper side is formed to be low and viewed from the side, the upper surface is formed obliquely with a predetermined angle.

In addition, the solar sensing unit 26 has a plurality of light receiving elements 26a formed on the surface thereof in an array in the form of rows and columns, so that the solar light is distributed when the sunlight is irradiated. Due to the position it is possible to recognize the irradiation angle of the sunlight, and also due to the input of the month (month) input to the function input unit 26 it is possible to recognize the irradiation angle of the sun.

The photocurrent generated from the solar sensing unit 26 is stored in the storage battery 38 to drive the first motor 12 and the second motor 14 using the stored current. .

The operation of the solar adaptive blinder apparatus according to the first embodiment of the present invention having the above-described configuration will be described in detail with reference to the accompanying drawings.

5A, 5B, and 5C are diagrams illustrating time-phase change values of photocurrent detected by the solar sensing unit of the solar adaptive blinder device according to the first embodiment of the present invention, and FIGS. 6A and 6B illustrate the present invention. FIG. 1 is a data diagram schematically illustrating seasonal variation of photocurrent detected through a solar sensing unit of a solar adaptive blinder device according to a first embodiment of FIG.

First, when the sun rises from the east, the upper surface of the solar sensing unit 26 installed on the outer wall of the building is convex, so that the light detection distribution on the light-receiving element array distributed on the upper surface thereof is as shown in FIG. 5A. Distributed together.

In addition, the data about the irradiation angle of sunlight according to the month-specific input value input to the function input unit 28 is read from the data storage unit 34.

As shown in FIG. 5A, at this time, since the angle of sun irradiation is small, the control unit may allow the first motor 12 to be reversely rotated so that the blinder piece 2 may not be opened. Generate a control signal at 36).

Then, the first motor 12 is reversely rotated and the lifting rope 4 wound around the lifting driving roller 6 is released while having a predetermined weight at the lower end of the blind piece 2. As a result, the blinder piece 2 is extended in the downward direction.

In addition, when the distribution of sunlight detected by the solar detector 26 shows a distribution as shown in FIG. 5B as time elapses, the irradiation angle of the sunlight becomes large, and thus the controller 36 stores the data. The storage unit 34 reads data on the opening length and installation angle of the blinder piece 2 and generates a control signal for the first and second motor drivers 30 and 32.

At this time, since the irradiation angle of sunlight is large, the first motor 12 is rotated forward so that the blinder piece 2 is positioned by a predetermined height, and the second motor 14 is rotated to rotate the angle adjusting roller. By rotating a small amount of (20), the angle of the blinder piece 2 is made by winding the first angle adjusting string 18a slightly upward.

On the other hand, as shown in Figure 5c at this time because the sun irradiation angle is a small state so that the first motor 12 can be reversely rotated to be maintained in a state that the opening of the blind piece 2 is not made The control unit 36 generates a control signal.

Then, the first motor 12 is reversely rotated and the lifting rope 4 wound around the lifting driving roller 6 is released, and the blinder is formed due to the weight of the blind supporter configured at the lower end of the blinder piece 2. The piece 2 is extended long in the downward direction.

In addition, in the case where the input for each month is made on the function input unit 28, the control unit 36 receives data about the monthly blinder installation angle and the open length from the data storage unit 34, that is, the irradiation angle of the sun. The first motor 12 and the second motor 14 are driven by reading data on the installation angle and the opening length of the blinder corresponding to.

On the other hand, as shown in Figure 6a the value of the photocurrent generated through the light-receiving element array in the summer, the sun according to the change of the season, such as the photocurrent generated through the light-receiving element array in winter as shown in Figure 6b By applying the data on the irradiation angle and the brightness of the blind to the opening of the blinder piece (2), the blinder piece (2) can be automatically driven optimally for humans in response to time and season.

On the other hand, the above-described solar adaptive blind drive device according to the first embodiment of the present invention can be freely modified without departing from the technical gist of the invention.

7 is a perspective view illustrating a state in which the solar adaptive blinder device according to the second embodiment of the present invention is applied to a vertical blinder.

Referring to this, the blinder drive unit housing 39 is fixedly coupled to the upper side of the window, the horizontal transfer motor 40 is coupled to the inner side of the housing is provided.

In addition, the first power transmission wheel 40a is coupled to the shaft of the horizontal motor 40, and the second power transmission wheel 42 to which the driving force generated from the first power transmission wheel 40a is applied. It is coupled to the inner predetermined portion.

On the other hand, the third power transmission wheel 44 for transmitting the driving force transmitted through the second power transmission wheel 42 to the other end is inverted in a vertical state is coupled to the inside of the blind drive unit housing 39. .

In addition, a fourth power transfer wheel 46 is provided at the other inner end of the blind drive unit housing 39 to be rotated by receiving a driving force generated from the third power transfer wheel 44.

Thus, when the transmission wire 48 is enclosed on the outer circumferential surfaces of the first, second, third, and fourth power transmission wheels 40a, 42, 44, 46, and is kept taut, the driving force generated from the horizontal transfer motor 40 is maintained. By sequentially transmitting the transmission wire 48 can be transported.

On the other hand, one side is coupled to the groove (not shown) formed on the inside of the blinder drive unit housing 39, the other side is provided with a support shaft 49 to which the power transmission gear 60 is coupled, the support shaft ( Sides 49 of the plurality of flow unit housings 50 are coupled to and supported through the inside thereof.

In addition, the flow part housing 50a is formed with a fixing protrusion 52 protruding at the front thereof, the fixing protrusion 52 is coupled to a predetermined portion of the transmission wire 48 to the transmission wire 48. Due to the transfer of the flow unit housing (50a) is to be transferred.

The power transmission gear 60 coupled to one end of the support shaft 49 is configured to receive the driving force generated from the angle adjustment motor 64 fixedly coupled to the inside of the blinder drive housing 39. It is engaged with the rotation gear 62 coupled to the shaft of the motor (64).

In addition, Figure 8 is a combined perspective view showing the angle adjustment portion in the vertical blinder of FIG.

Referring to this, a plurality of slots 49a are formed in both predetermined portions of the support shaft 49 horizontally installed inside the blind drive unit housing 39, and a plurality of slots 49a may be inserted into the slot 49a. The worm 66 is provided on the inner circumferential surface of the engaging projection 66a.

In addition, a worm wheel 68 having a gear formed on an outer circumferential surface thereof is provided to be engaged with the outer gear of the worm 66 in a vertical direction, and the fixed shaft 54 penetrates the center of the wheel wheel 68. do.

The operation of the solar adaptive blinder device according to the second embodiment of the present invention having the above-described configuration will be described in detail with reference to the accompanying drawings.

First, when the automatic blind mode adjustment mode is set in the function input unit 28, the irradiation angle and the irradiation amount of the sun are detected by the solar detector 26, and the detection signal is applied by the controller 36. At the same time, the electrical storage unit 38 receives the photocurrent generated by the solar sensing unit 26.

As a result, the control unit 36 rotates the horizontal transfer motor 40 by reading blind control data corresponding to the applied irradiation angle and the irradiation amount from the data storage unit 34.

At this time, when the horizontal motor 40 is rotated in one direction, the first power transmission wheel 40a coupled to the shaft of the horizontal motor 40 is rotated so that the transmission wire 48 is wound around the outer circumferential surface of the wheel. Is transferred, and the flow part housing 50a having the fixing protrusion 52 coupled to one side of the transmission wire 48 at its front side is moved in the direction in which the vertical blinder piece 56 is folded.

In addition, the flow part housing 50a is moved in the direction in which the vertical blinder piece 56 is folded, and pushes the plurality of flow part housings 50b to 50n installed at one side thereof to one side of the blinder device so that the vertical blinder piece ( 56) is folded.

On the other hand, when the irradiation angle of the sunlight detected by the solar detector 26 and the amount of irradiation above a predetermined predetermined value at night or almost no irradiation amount are detected, the controller 36 stores the corresponding data in the data storage unit 34. Read from) to cause the horizontal motor 40 to rotate in reverse.

Then, as the transfer wire 48 is transferred, the flow unit housing 50a fixed to one side is transferred to the transfer direction side of the transfer wire 48, and a plurality of the flow unit housings 50a and the side thereof are provided. When the flow unit housing 50a is moved as the flow unit housings 50b to 50n installed in parallel are connected to the extension cord 58, the plurality of flow unit housings 50b to 50n on one side thereof are transferred at regular intervals. Since the vertical blinder piece 56 is spread out.

In addition, when the vertical blinder piece 56 is unfolded at a predetermined position and the angle of the vertical blinder piece 56 is required due to the irradiation angle of the sun, the controller 64 may control the angle adjusting motor 64. Generates a predetermined pulse signal at.

Then, the angle adjusting motor 64 is rotated in response to the pulse signal to rotate the rotation gear 62 coupled to the shaft, and the power transmission gear 60 meshed with the rotation gear 62. Will be rotated.

In addition, the support shaft 49 is rotated due to the rotation of the power transmission gear 60 to the coupling protrusion 66a coupled to the slot 49a formed on the outer circumferential surface of the support shaft 49. This causes the worm 66 to rotate.

In addition, as the worm wheel 68 engaged with the worm 66 is rotated, the angle of the vertical blinder piece 56 maintains a desired angle.

In addition, in the solar adaptive blinder apparatus according to the first and second embodiments of the present invention, the indoor illuminance value detected from the illuminance sensing unit 29 provided in a predetermined part of the room is compared with a predetermined illuminance value. This makes it possible to automatically flash the lights of the room.

On the other hand, the solar adaptive blinder apparatus according to the second embodiment of the present invention can be freely modified within the scope not departing from the technical gist.

As described above, according to the solar adaptive blinder device according to the present invention, it is possible to use the convenient blinder by reading the data according to time and season so that the blinder opening and angle can be precisely adjusted. In offices, etc., it is possible to automatically lift and lower the blinds, and at this time, it is possible to precisely control a plurality of blinds using a single processor, thereby creating an optimal working environment and a living environment for humans.

In addition, since the battery can be stored in the battery using the solar cell array provided in the solar sensing unit, the blinder can be automatically operated by using the stored power without having to manually operate the blinder even in the daylight during a power failure. can do.

In addition, the illuminance value of the sunlight flowing through the window from the illuminance sensing unit provided in the room is compared with a preset setting so that the illumination of the room may be automatically blinked, thereby saving energy.

Claims (6)

A long hole (2a) through which the lifting rope (4) passes on its surface and an incision hole (2b) through which the rope for angle adjustment passes through the upper and lower ends of the window to block or apply irradiation of sunlight. A blinder including a plurality of the formed blinder pieces 2, A solar detector 26 installed on an outer wall of the building to adjust the opening length of the blinder and the installation angle of the blinder piece 2 to correspond to the irradiation angle of the sun and the light quantity of the sunlight; ; A storage battery 38 configured to use the load current by accumulating the photocurrent generated from the solar sensing unit 26; In order to adjust the opening length of the blinder and the installation angle of the blinder piece (2), the automatic / manual mode conversion button is installed so that the mode conversion between automatic and manual is possible, and the month input button is provided with a function input unit ( 28); An illuminance detecting unit 29 provided at a predetermined position in the room where the blind is provided to detect illuminance due to sunlight flowing into the room through a window; Opening length, installation angle and blinking of the blinder piece 2 corresponding to the irradiation distribution of the sunlight detected by the solar detector 26 and the moon input input from the function input unit 28 A data storage unit 34 for which illuminance data is preset; The irradiation angle of sunlight and the wall input input from the function input unit 28 are received from the solar sensing unit 26, and data about the opening length and installation angle of the blinder piece 2 is received for the data storage unit ( 34 to generate a control signal to the elevating motor 12 and the angle adjusting motor 14 to drive the elevating driving roller 6 and the angle adjusting roller 20 to raise and lower the blind piece 2; Adaptive blinder device, characterized in that consisting of a control unit 36 to make the angle adjustment. The solar cell detecting unit 26 of claim 1, wherein the solar sensor 26 is configured to have a convex upper surface so as to detect the irradiation angle and the amount of sunlight through the irradiation distribution of solar light. Solar adaptive blinder device characterized in that the array is formed. The method of claim 1, wherein a worm is coupled to the shaft of each of the motors (12,14) and a worm wheel is formed on one end of each of the rollers (6, 20) to be engaged with the worm. Device. According to claim 1, wherein the photocurrent applied from the solar sensing unit 26, the indoor illuminance applied from the illuminance detecting unit 29 is a predetermined illuminance value to the data storage 34 and the control unit 36 And a switching unit (33) which is switched by receiving a predetermined control signal generated. In the vertical blinder including a plurality of vertical blinder piece 56, which is spread vertically across the top and bottom of the window to block or apply the irradiation of sunlight, The solar sensing unit 26 is installed on the outer wall of the building to adjust the opening length of the vertical blinder and the installation angle of the vertical blinder piece 56 according to the irradiation angle of the sun and the amount of sunlight. )Wow; In order to adjust the opening length of the vertical blinder and the installation angle of the vertical blinder piece 56, each mode conversion button is installed so that mode conversion can be performed automatically and manually, and a month input button is provided. 28; The irradiation distribution of the sunlight detected by the solar detector 26 and the data of the opening length and installation angle of the blinder piece 2 corresponding to the moon input input from the function input unit 28 are preset. A data storage unit 34; The data storage unit receives the irradiation angle of sunlight from the solar detector 26 and the wall input input from the function input unit 28 to receive data about the opening length and installation angle of the vertical blinder piece 56. The control unit 36 reads from the 34 and generates a control signal to the horizontal transfer motor 40 and the angle adjusting motor 64 so that the vertical blinder piece 56 can be extended / contracted and the angle can be adjusted. Solar adaptive blinder device, characterized in that consisting of. The worm (66) according to claim 2, wherein the worm (66) is provided inside the blinder device to transmit the rotational force generated from the angle adjusting motor (64) in the vertical direction so that the angle of the vertical blinder piece (56) can be adjusted. And a worm wheel 68 is provided with a solar adaptive blinder device.