CN203097679U - Automatic light control glass and curtain wall - Google Patents

Abstract

An automatic light control glass (100) and a curtain wall (200) are provided. The automatic light control glass (100) includes a first glass (150), a liquid crystal dot matrix (160), a liquid crystal dot matrix drive module (140), a light sensor (120), a microprocessor (130), and a power supply module (110). The power supply module (110) is used for providing power to the automatic light control glass (100). The liquid crystal dot matrix (160) is arranged on the surface of the first glass (150). The light sensor (120) is used for sensing the light illumination intensity and correspondingly outputting signals representing the magnitude of the light illumination intensity. The microprocessor (130) is used for outputting corresponding control signals according to the output signals of the light sensor (120). The liquid crystal dot matrix driving module (140) is used for outputting drive signals according to the control signals of the microprocessor (130) to adjust the light permeability of the liquid crystal dot matrix (160), so as to adjust the light permeability of the automatic light control glass (100).

Description

A kind of automatic control light glass and curtain wall

Technical field

The utility model relates to constructional materials, relates in particular to a kind of automatic control light glass and curtain wall.

Background technology

Along with process of urbanization, glass uses more and more widely because of characteristics such as light transmission is good, appearance looks elegant under construction.At present, glass not only is used for window, indoor partition, also is used for building curtain wall in a large number, and becomes fashion trend gradually.But the translucidus that glass is good might cause indoor and outdoor not have the sight line obstruct or indoor light is crossed problems such as strong.Such as, the glass that office adopts usually cuts off the easy confidentiality that influences company's confidential session.And for example, curtain wall can't intercept the sunlight direct projection and will make the indoor greenhouse that becomes during scorching summer.

At above problem, a kind of common traditional solution is on window, indoor partition and curtain wall curtain to be set, and comes brightness in the control room by the folding curtain.But the defective of curtain is well-known, not only need when mounted to set up various accessories, and the easily stained and frequent replacing cleaning of cord.In addition, also can influence the sight of luxurious curtain wall originally attractive in appearance.

Another kind of common traditional solution is the color that changes glass by the method for pad pasting, spraying.But, can only remain a kind of color through the glass of pad pasting or spraying, so its light transmission remains unchanged also.So, can't correspondingly regulate or change with intensity of illumination through the translucidus of the glass of pad pasting or spraying.A little less than when natural lighting intensity is more weak, inciting somebody to action extremely, thereby need to borrow fluorescence lamp throw light on through the light in the glass inlet chamber of pad pasting or spraying.Obviously, the traditional solution of this kind can not make full use of natural light, can't satisfy the requirement of modern architecture material for environmental protection and energy saving.

The utility model content

In view of this, the technical problems to be solved in the utility model provides a kind of automatic control light glass and curtain wall, can regulate translucidus automatically according to intensity of illumination, thus the brightness automatically in the equalization chamber, and utilize natural light as much as possible to satisfy of the requirement of modern architecture material for environmental protection and energy saving.

The utility model provides a kind of automatic control light glass, comprises first glass, liquid crystal dot matrix, liquid crystal dot matrix driver module, optical sensor, microprocessor and supply module.Wherein, described supply module is used to described automatic control light glass power supply.Described liquid crystal dot matrix is arranged at described first glass surface.Described optical sensor is used for the sensing intensity of illumination, and the signal of intensity of illumination size is represented in corresponding output.Described microprocessor is used for the signal according to the representative intensity of illumination size of described optical sensor output, corresponding output control signal.Described liquid crystal dot matrix driver module is used for the control signal according to described microprocessor output, and corresponding output drive signal is regulated the light transmission of described liquid crystal dot matrix, thereby regulates the light transmission of described automatic control light glass.

As further improvement of the utility model, described microprocessor comprises power pins, one group of signal detection pin and a plurality of output pin.Wherein, described power pins links to each other with described supply module.One group of signal detection pin is used to detect the signal of the representative intensity of illumination size of described optical sensor output.A plurality of output pins are used to output control signals to described liquid crystal dot matrix driver module.

As further improvement of the utility model, described optical sensor comprises light resistor and resistance.The two ends of described light resistor link to each other with the signal detection pin of described microprocessor respectively.One end of described resistance links to each other other end ground connection with an end of light resistor.

As further improvement of the utility model, described supply module comprises rechargeable battery, solar cell, diode, low pressure difference linear voltage regulator, polar capacitor and nonpolar electric capacity.Wherein, to utilize solar energy be the charging of described rechargeable battery to described solar cell.The positive pole of described diode links to each other with the positive pole of solar cell, and negative pole links to each other with described rechargeable battery is anodal.The earth terminal of described low pressure difference linear voltage regulator links to each other with the negative pole of rechargeable battery and solar cell, and input links to each other with the positive pole of described rechargeable battery, and output links to each other with the power pins of described microcontroller.The positive pole of described polar capacitor links to each other with the output of described low pressure difference linear voltage regulator, and negative pole links to each other with the earth terminal of described low pressure difference linear voltage regulator.Described nonpolar electric capacity is connected between the earth terminal and output of described low pressure difference linear voltage regulator.

As further improvement of the utility model, described automatic control light glass also comprises second glass, forms interlayer with described first glass, is used for described at least one liquid crystal dot matrix is sandwiched between the two.

The utility model also provides a kind of automatic control light curtain wall, comprises a plurality of first glass, a plurality of liquid crystal dot matrix, liquid crystal dot matrix driver module, optical sensor, microprocessor and supply module.Wherein, described a plurality of liquid crystal dot matrix is arranged at described a plurality of first glass surface respectively.Described supply module is used to described automatic control light glass power supply.Described optical sensor is used for the sensing intensity of illumination, and the signal of intensity of illumination size is represented in corresponding output.Described microprocessor is used for the signal according to the representative intensity of illumination size of described optical sensor output, corresponding output control signal.Described liquid crystal dot matrix driver module is used for the control signal according to described microprocessor output, and corresponding output drive signal is regulated the light transmission of described a plurality of liquid crystal dot matrix, thereby regulates the light transmission of described automatic control light curtain wall.

As further improvement of the utility model, described microprocessor comprises power pins, one group of signal detection pin and a plurality of output pin.Wherein, described power pins links to each other with described supply module.The signal detection pin is used to detect the signal of the representative intensity of illumination size of described optical sensor output.A plurality of output pins are used to output control signals to described liquid crystal dot matrix driver module.

As further improvement of the utility model, described optical sensor comprises light resistor and resistance.The two ends of described light resistor link to each other with the signal detection pin of described microprocessor respectively.One end of described resistance links to each other other end ground connection with an end of light resistor.

As further improvement of the utility model, described supply module comprises rechargeable battery, solar cell, diode, low pressure difference linear voltage regulator, polar capacitor and nonpolar electric capacity.Wherein, to utilize solar energy be the charging of described rechargeable battery to described solar cell.The positive pole of described diode links to each other with the positive pole of solar cell, and negative pole links to each other with described rechargeable battery is anodal.The earth terminal of described low pressure difference linear voltage regulator links to each other with the negative pole of rechargeable battery and solar cell, and input links to each other with the positive pole of described rechargeable battery, and output links to each other with the power pins of described microcontroller.The positive pole of described polar capacitor links to each other with the output of described low pressure difference linear voltage regulator, and negative pole links to each other with the earth terminal of described low pressure difference linear voltage regulator.Described nonpolar electric capacity is connected between the earth terminal and output of described low pressure difference linear voltage regulator.

As further improvement of the utility model, described automatic control also comprises a plurality of second glass for the light curtain wall, forms interlayer with described a plurality of first glass respectively, is used for described liquid crystal dot matrix is sandwiched between the two.

Automatic control light glass and curtain wall that the utility model provides, make microprocessor correspondingly control the translucidus that the liquid crystal dot matrix driver module is regulated liquid crystal dot matrix by the photosensor senses intensity of illumination, thereby make the translucidus of controlling light glass and curtain wall automatically to regulate automatically according to the variation of intensity of illumination according to the intensity of illumination of optical sensor institute sensing.Therefore, thereby automatic control light glass that the utility model provides and curtain wall can be regulated translucidus brightness in the equalization chamber automatically automatically according to intensity of illumination, thereby and utilize natural light to satisfy the requirement of modern architecture material for environmental protection and energy saving as much as possible.

Description of drawings

Fig. 1 is the module diagram of the automatic control light glass that provides of the utility model;

Fig. 2 is the schematic diagram of another embodiment of the automatic control light glass that provides of the utility model; ,

Fig. 3 is the physical circuit schematic diagram of the automatic control light glass that provides of the utility model;

Fig. 4 is the module diagram of the automatic control light curtain wall that provides of the utility model;

Fig. 5 is the schematic diagram of another embodiment of the automatic control light curtain wall that provides of the utility model.

The specific embodiment

Be described in further detail below in conjunction with accompanying drawing and embodiment of the present utility model.

The module diagram of the automatic control light glass 100 that Fig. 1 provides for the utility model.As shown in Figure 1, the automatic control light glass 100 that provides of the utility model comprises supply module 110, optical sensor 120, microprocessor 130, liquid crystal dot matrix driver module 140, first glass 150 and liquid crystal dot matrix 160.

Wherein, supply module 110 is used to described automatic control light glass 100 power supplies.Optical sensor 120 is used for the sensing intensity of illumination, and the signal of intensity of illumination size is represented in corresponding output.Microprocessor 130 is used for passing according to described light the signal of the representative intensity of illumination size of device 120 outputs, correspondingly outputs control signals to described liquid crystal dot matrix driver module 140.Liquid crystal dots formation driver module 140 is used for the control signal according to microprocessor 130 outputs, and the driving signal that produces relevant voltage is to liquid crystal dots formation 160, thus the light transmission of regulating liquid crystal dot matrix 160.

Liquid crystal dot matrix 160 is arranged at the surface of first glass 150.According to the size of first glass 150 and the size difference of liquid crystal dots formation 160, one or more liquid crystal dot matrix 160 can be set on the surface of first glass 150.The size of first glass 150 shown in Fig. 1, the size of liquid crystal dot matrix 160 that is arranged at first glass, 150 surfaces and quantity are only for cooperating manual to understand the automatic control light glass 100 that the utility model provides better.

In the present embodiment, the signal that optical sensor 120 is exported correspondingly changes with the variation of intensity of illumination, and microprocessor 130 will correspondingly be exported the driving voltage of signals of control signal control liquid crystal dot matrix driver module 140 outputs according to the signal of described optical sensor 120 outputs.Therefore, microprocessor 130 can be according to the variation of intensity of illumination and is correspondingly controlled the driving voltage of signals that liquid crystal dot matrix driver module 140 is exported.Correspondingly, liquid crystal dot matrix driver module 140 can correspondingly be regulated it according to the variation of intensity of illumination and drive voltage of signals, and then the light transmission of control liquid crystal dot matrix 160.Because liquid crystal dot matrix 160 is arranged at the surface of first glass 150 in the automatic control light glass 100, therefore the variation of the liquid crystal dot matrix 160 light transmissions light transmission that will cause controlling light glass 100 automatically correspondingly changes, thereby realizes that the light transmission of control light glass 100 is regulated automatically with the size of intensity of illumination automatically.

Fig. 2 is the schematic diagram of another embodiment of the automatic control light glass that the utility model proposes.As shown in Figure 2, the difference among the automatic control light glass among Fig. 2 100 and Fig. 1 is also to comprise second glass 170.Second glass 170 forms interlayer with described first glass 150, is used for liquid crystal dot matrix 160 is sandwiched between the two.

Fig. 3 is the physical circuit schematic diagram of the automatic control light glass that the utility model proposes.As shown in Figure 3, the automatic control light glass 100 that provides of the utility model comprises supply module 110, optical sensor 120, microprocessor 130, liquid crystal dot matrix driver module 140, first glass 150 and liquid crystal dot matrix 160.

Microprocessor 130 comprises power pins VDD, grounding pin GND, one group of signal detection pin AD0 and AD1, a plurality of output pin PB0-PB3.Wherein, power pins VDD links to each other with supply module 100, grounding pin GDD ground connection.Described signal detection pin AD0 and AD1 link to each other with optical sensor 120, are used to detect the signal of the representative intensity of illumination size of optical sensor 120 outputs.Described output pin PB0-PB3 is used to output control signals to liquid crystal dot matrix driver module 140, drives the driving voltage of signals that mould sound 140 is exported to regulate liquid crystal dot matrix.For understanding the automatic control light glass 100 that the utility model proposes better, only show the part-structure of microprocessor 130 among Fig. 3.

Supply module 110 comprises diode D1, rechargeable battery V1, solar cell V2, low pressure difference linear voltage regulator (Low Drop-Out Voltage Regulator) Q1, polar capacitor C1 and nonpolar capacitor C 2.Wherein, to be used to utilize solar energy be described rechargeable battery V1 power supply to described solar cell V2.The negative pole of described diode D1 links to each other with the positive pole of described rechargeable battery V1, and the positive pole of anodal and described solar cell V2 links to each other.The minus earth of described rechargeable battery V1 and solar cell V2.The earth terminal GND of described low pressure difference linear voltage regulator Q1 links to each other with the negative pole of rechargeable battery V1 and solar cell V2, and input Vin links to each other with the positive pole of described rechargeable battery V1, and output end vo ut is connected in the power pins VDD of described microprocessor 130.The positive pole of described polar capacitor C1 links to each other with the output end vo ut of described low pressure difference linear voltage regulator Q1, and negative pole links to each other with the earth terminal GND of described low pressure difference linear voltage regulator Q1.Described nonpolar capacitor C 2 is connected between the earth terminal GND and output end vo ut of described low pressure difference linear voltage regulator Q1.

Optical sensor 120 comprises light resistor R1 and resistance R 2.Wherein, the two ends of light resistor R1 link to each other with the signal detection pin AD0 and the AD1 of microprocessor 100 respectively.One end of resistance R 2 links to each other other end ground connection with the end of light resistor R1.The resistance of light resistor R1 correspondingly changes with intensity of illumination, and the signal that makes optical sensor 120 correspondingly export to represent the intensity of illumination size is to microprocessor 130.

Liquid crystal dot matrix 160 comprises the first polarization filter, second polarization filter and the liquid crystal.Wherein, the direction of the described second polarization filter is vertical with the described first polarization filter.Described liquid crystal riddles between the described first polarization filter and the second polarization filter.

Under normal circumstances,, turn 90 degrees, from the second polarization filter, pass again so light passes can be turned round by liquid crystal molecule behind first polarization filter because the first polarization filter and second polarization have been full of the liquid crystal molecule of distortion between the filter.

When liquid crystal dot matrix driver module 140 is exported the corresponding driving signal according to the control signal of microprocessor 130 outputs, liquid crystal molecule in the liquid crystal dot matrix 160 between the first polarization filter and the second polarization filter can rearrange adjusting according to driving signal, make light no longer turn round and turn 90 degrees and from the second polarization filter, to pass, thereby regulate the translucidus of liquid crystal dot matrix 160, make that the light transmission of control light glass 100 is regulated automatically with the size of intensity of illumination automatically.

The module diagram of the automatic control light curtain wall 200 that Fig. 4 provides for the utility model.As shown in Figure 4, control light curtain wall 200 automatically and comprise supply module 210, optical sensor 220, microprocessor 230, liquid crystal dot matrix driver module 240, a plurality of first glass 250 and a plurality of liquid crystal dot matrix 260.Wherein, the function and the structure of supply module 110, optical sensor 120, microprocessor 130 and liquid crystal dot matrix driver module 140 among the supply module 210 among Fig. 4, optical sensor 220, microprocessor 230 and liquid crystal dot matrix driver module 240 and Fig. 1 are identical, so no longer repeat.

Automatically control light curtain wall 200 also comprises first glass 250 of a plurality of combinations, and a plurality of liquid crystal dot matrix 260 are arranged at described a plurality of first glass 250 respectively on the surface.According to the size of first glass 250 and the size difference of liquid crystal dots formation 260, one or more liquid crystal dot matrix 260 can be set on the surface of first glass 250.The size and the quantity of first glass 250 shown in Fig. 4, the size of liquid crystal dot matrix 260 that is arranged at first glass, 250 surfaces and quantity are only for cooperating manual to understand the automatic control light curtain wall 200 that the utility model provides better.

In the present embodiment, optical sensor 220 is according to the corresponding signal of representing the intensity of illumination size of variation output of intensity of illumination, and microprocessor 230 correspondingly outputs control signals to liquid crystal dot matrix driver module 240 according to the signal of described representative intensity of illumination size.Therefore, microprocessor 230 can correspondingly be controlled the driving voltage of signals of liquid crystal dot matrix driver module 240 outputs according to the variation of intensity of illumination.Correspondingly, liquid crystal dot matrix driver module 240 can correspondingly be regulated it according to the variation of intensity of illumination and drive voltage of signals, and then regulates the light transmission of liquid crystal dot matrix 260.Because liquid crystal dot matrix 260 is arranged at the surface of first glass 250, so the light transmission that the variation of liquid crystal dot matrix 260 light transmissions will cause controlling light curtain wall 200 automatically correspondingly changes light transmission adjusting automatically with the size of intensity of illumination of the feasible light of control automatically curtain wall 200.

The schematic diagram of the another kind of embodiment of the automatic control light curtain wall 200 that Fig. 5 provides for the utility model.As shown in Figure 5, the difference of controlling light curtain wall 200 and Fig. 4 among Fig. 5 automatically is also to comprise a plurality of second glass 270, forms interlayers with described a plurality of first glass 260 respectively, is used for liquid crystal dot matrix 250 is sandwiched between the two.

Automatic control light glass and curtain wall that the utility model provides, make microprocessor correspondingly control the translucidus that the liquid crystal dot matrix driver module is regulated liquid crystal dot matrix by the photosensor senses intensity of illumination, thereby make the translucidus of controlling light glass and curtain wall automatically to regulate automatically according to the variation of intensity of illumination according to the intensity of illumination of optical sensor institute sensing.Therefore, thereby automatic control light glass that the utility model provides and curtain wall can be regulated brightness in the translucidus equalization chamber automatically according to intensity of illumination, thereby and utilize natural light to satisfy the requirement of modern architecture material for environmental protection and energy saving as much as possible.

Above content be in conjunction with concrete preferred implementation to further describing that the utility model is done, can not assert that concrete enforcement of the present utility model is confined to these explanations.For the utility model person of an ordinary skill in the technical field, under the prerequisite that does not break away from the utility model design, can also make some simple deduction or replace, all should be considered as belonging to protection domain of the present utility model.

Claims (10)

1. control light glass automatically for one kind, it is characterized in that, comprising:

First glass;

Liquid crystal dot matrix is arranged at described first glass surface;

Supply module is used to described automatic control light glass power supply;

Optical sensor is used for the sensing intensity of illumination, and the signal of intensity of illumination size is represented in corresponding output;

Microprocessor is used for the signal according to the representative intensity of illumination size of described optical sensor output, corresponding output control signal;

The liquid crystal dot matrix driver module is used for the control signal according to described microprocessor output, and corresponding output drive signal is regulated the light transmission of described liquid crystal dot matrix, thereby regulates the light transmission of described automatic control light glass.

2. automatic control light glass according to claim 1 is characterized in that described microprocessor comprises:

Power pins links to each other with described supply module;

One group of signal detection pin is used to detect the signal of the representative intensity of illumination size of described optical sensor output; And

A plurality of output pins are used to output control signals to described liquid crystal dot matrix driver module.

3. automatic control light glass according to claim 2 is characterized in that described optical sensor comprises:

Light resistor, its two ends link to each other with the signal detection pin of described microprocessor respectively; And

First resistance, the one end links to each other other end ground connection with an end of light resistor.

4. automatic control light glass according to claim 2 is characterized in that described supply module comprises:

Rechargeable battery;

Solar cell, being used to utilize solar energy is described rechargeable battery charging;

Diode, its positive pole links to each other with the positive pole of described solar cell, and negative pole links to each other with described rechargeable battery is anodal;

Low pressure difference linear voltage regulator, its earth terminal links to each other with the negative pole of rechargeable battery and solar cell, and input links to each other with the positive pole of described rechargeable battery, and output links to each other with the power pins of described microprocessor;

Polar capacitor anodally links to each other with the output of described low pressure difference linear voltage regulator, and negative pole links to each other with the earth terminal of described low pressure difference linear voltage regulator; And

Nonpolar electric capacity is connected between the earth terminal and output of described low pressure difference linear voltage regulator.

5. according to any described automatic control light glass of claim 1 to 4, it is characterized in that, also comprise second glass, form interlayer, be used for described at least one liquid crystal dot matrix is sandwiched between the two with described first glass.

6. control the light curtain wall automatically for one kind, it is characterized in that, comprising:

A plurality of first glass;

A plurality of liquid crystal dot matrix are arranged at described a plurality of first glass surface respectively;

Supply module is used to described automatic control light curtain wall power supply;

Optical sensor is used for the sensing intensity of illumination, and the signal of intensity of illumination size is represented in corresponding output;

Microprocessor is used for the signal according to the representative intensity of illumination size of described optical sensor output, corresponding output control signal;

The liquid crystal dot matrix driver module is used for the control signal according to described microprocessor output, and corresponding output drive signal is regulated the light transmission of described a plurality of liquid crystal dot matrix, thereby regulates the light transmission of described automatic control light curtain wall.

7. automatic control light curtain wall according to claim 6 is characterized in that described microprocessor comprises:

Power pins links to each other with described supply module;

One group of signal detection pin is used to detect the signal of the representative intensity of illumination size of described optical sensor output; And

A plurality of output pins are used to output control signals to described liquid crystal dot matrix driver module.

8. the automatic control light curtain wall of stating according to claim 7 is characterized in that described optical sensor comprises:

Light resistor, its two ends link to each other with the signal detection pin of described microprocessor respectively; And

Resistance, the one end links to each other other end ground connection with an end of light resistor.

9. automatic control light curtain wall according to claim 7 is characterized in that described supply module comprises:

Rechargeable battery;

Solar cell, being used to utilize solar energy is described rechargeable battery charging;

Diode, its positive pole links to each other with the positive pole of described solar cell, and negative pole links to each other with described rechargeable battery is anodal;

Low pressure difference linear voltage regulator, its earth terminal links to each other with the negative pole of rechargeable battery and solar cell, and input links to each other with the positive pole of described rechargeable battery, and output links to each other with the power pins of described microprocessor;

Polar capacitor anodally links to each other with the output of described low pressure difference linear voltage regulator, and negative pole links to each other with the earth terminal of described low pressure difference linear voltage regulator; And

Nonpolar electric capacity is connected between the earth terminal and output of described low pressure difference linear voltage regulator.

10. according to any described automatic control light curtain wall of claim 6 to 9, it is characterized in that, also comprise a plurality of second glass, form interlayer with described a plurality of first glass respectively, be used for described liquid crystal dot matrix is sandwiched between the two.

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