CN205530856U - Automatic wind response type constant temperature curtain system - Google Patents

Abstract

The utility model discloses an automatic wind response type constant temperature curtain system, including inside and outside layer glass, the cavity intermediate layer has between the inside and outside layer glass, and the cavity intermediate layer passes through shutter and outside intercommunication, and the shutter receives motor drive, and outer glass is equipped with wind -force detection module and temperature detection module, and inlayer glass is equipped with control module and drive module, and control module and drive module open or close the shutter according to wind -force detection module and temperature detection module state. Wherein, set up attemperator at the cavity intermediate layer, refrigerate or heat the air in curtain intermediate level to form the one deck heat preservation, make the temperature of the inboard building of curtain invariable relatively, do not receive ambient temperature's influence, reach homothermal effect, to sum up, reach 80% energy -conserving effect.

Description

Automatic wind induction type constant temperature curtain wall system

Technical field

This utility model relates to building decoration technology field, especially automatic wind induction type constant temperature curtain wall system.

Background technology

Along with improving constantly of living standard, the fast development of building trade, requirement to construction style is more and more higher, in recent years, glass curtain wall rises throughout the country, extensive concern by numerous builders, particularly point type glass curtain wall is of greatest concern, which advantage this has with regard to necessary understanding point type glass curtain wall, point type glass curtain wall is an emerging technology, what it embodied is the circulation inside and outside building and fusion, changes over and shows the traditional method of window, curtain wall, zenith with glass, it is emphasised that the transparency of glass.Through glass, simple supporting structure system, it can be clearly seen that the total system of supported glass curtain wall, is converted into visuality, sight and expression power by people.

Such as, existing notification number is that the patent of CN105220999A discloses a kind of electric driven glass curtain wall point type opening door-leaf, it is fixed on main body fixed mount by connector, including fastening glass panels and rotation glass plate can be opened, the described upper end opening rotation glass plate and lower end are respectively equipped with a pair upper end splice system and a pair lower end splice system with fastening glass panels contact position, described upper end splice system is all symmetrical set with lower splice system, it is provided with at the edge of described lower splice system to fix with main body fixed mount edge and can promote and can open the electric window-opening device rotating glass plate.

Glass curtain wall in above-mentioned patent is opened or is closed by electronic, is whether all to need to go artificially to control opening or closing, it is impossible to control glass curtain wall intelligently according to the change of external environment and open or close.

Utility model content

The deficiency existed for prior art, the purpose of this utility model is to provide a kind of automatic wind induction type constant temperature curtain wall system, it is possible to controls glass curtain wall according to the size of external wind intelligently with the height of temperature and opens.

For achieving the above object, this utility model provides following technical scheme: a kind of automatic wind induction type constant temperature curtain wall system, including inner layer glass and glass outer, between described inner layer glass and glass outer, there is hollow sandwich, described hollow sandwich passes through shutter and ft connection, and described shutter is driven by motor, and the outside of described glass outer is provided with wind-force detection module and temperature detecting module, the outside of described inner layer glass is provided with control module and drives module

Described wind-force detection module exports wind-force detection signal when outdoor wind-force exceedes setting value；

Described temperature detecting module is output temperature detection signal when outside humidity exceedes setting value；

Output control signal when described control module receives wind-force detection signal and temperature detection signal at the same time；

Described driving module drives motor to open shutter in response to control signal.

By technique scheme, when extraneous temperature is higher, but when wind is the biggest, now, if opening glass curtain wall, indoor constantly ventilate with outdoor, and heat exchange occurs, and indoor holding can be made dry and comfortable, now need not shut glass curtain wall open air-conditioning；It addition, when outside air temperature is higher, when wind is less, can there is ventilating problem and sultry in indoor；It addition, when ambient temperature is relatively low, when wind is bigger, if opening glass curtain wall can make indoor cold；Equally, when ambient temperature is relatively low, and wind is less, if opening glass curtain wall also can make indoor cold；Based on above four kinds of situations, control module is only higher in ambient temperature, and is opened by glass curtain wall when wind is bigger, can not turn on the aircondition in this case, energy-conservation.

This utility model is further arranged to: described control module includes AND circuit and processor,

Wind-force is detected signal and temperature detection signal and exports to AND circuit by wind-force detection module and temperature detecting module respectively, and the outfan of AND circuit is connected to processor；

Processor controls pwm signal and the DIR signal of control motor steering of electric machine rotation according to AND circuit to the operation result output of wind-force detection signal and temperature detection signal.

This utility model is further arranged to: described control module also includes reversing unit, and it is in the DIR-A signal of DIR signal and anti-phase in the DIR-B signal of DIR signal that DIR signal is converted into a homophase by described reversing unit；

Described driving module is H bridge, receives DIR-A signal and DIR-B signal control motor rotates.

This utility model is further arranged to: be coupled with fuse-link between common port and the power supply of described two brachium pontis of H bridge.

This utility model is further arranged to: described wind-force detection module includes single-shot trigger circuit, and the triggering signal of described single-shot trigger circuit is provided by resistance strain gage.

This utility model is further arranged to: the resistance of described resistance strain gage increases with pressure and reduces, and provides to single-shot trigger circuit and triggers signal.

This utility model is further arranged to: the outfan of described single-shot trigger circuit connects display lamp.

This utility model is further arranged to: described temperature detecting module includes single-shot trigger circuit, and the triggering signal of described single-shot trigger circuit is provided by humistor.

This utility model is further arranged to: the resistance of described humistor increases with suffered ambient humidity and reduces, and provides to single-shot trigger circuit and triggers signal.

This utility model is further arranged to: the outfan of described single-shot trigger circuit connects display lamp.

By taking technique scheme, being shown by display lamp, when outside air temperature is relatively low, corresponding display lamp does not works, and when outside air temperature is higher, corresponding display lamp is shinny；When not blowing in the external world, corresponding display lamp does not works, and when blowing in the external world, corresponding display lamp is shinny；So user stays indoor and can know the weather condition in the external world.

Accompanying drawing explanation

Fig. 1 is the structural representation of glass curtain wall；

Fig. 2 is control block diagram in the present embodiment；

Fig. 3 is the schematic diagram of wind-force detection module；

Fig. 4 is the schematic diagram of temperature detecting module；

Fig. 5 is the schematic diagram one of control module；

Fig. 6 is the schematic diagram two of control module；

Fig. 7 is the schematic diagram driving module.

Reference: 1, inner layer glass；2, glass outer；3, hollow sandwich；4, shutter；100, wind-force detection module；200, temperature detecting module；300, control module；310, processor；320, reversing unit；400, module is driven.

Detailed description of the invention

Hereinafter, embodiment of the present utility model is illustrated.

With reference to Fig. 1, a kind of automatic wind induction type constant temperature curtain wall system, including inner layer glass 1 and glass outer 2, there is between inner layer glass 1 and glass outer 2 hollow sandwich 3, hollow sandwich 3 is by shutter 4 and ft connection, shutter 4 is driven by motor, and the outside of glass outer 2 is provided with wind-force detection module 100 and temperature detecting module 200, and the outside of inner layer glass 1 is provided with control module 300 and drives module 400.

With reference to Fig. 2, for the control block diagram in this example, wind-force detection module 100 exports wind-force detection signal when outdoor wind-force exceedes setting value；Temperature detecting module 200 is output temperature detection signal when outside humidity exceedes setting value；Output control signal when control module 300 receives wind-force detection signal and temperature detection signal at the same time；Module 400 is driven to drive motor to open shutter 4 in response to control signal.

With reference to Fig. 3, in the present embodiment, wind-force detection module 100 is single-shot trigger circuit, when resistance strain gage R pressure experienced is bigger, the resistance of resistance strain gage R reduces, common node in resistance strain gage R and potentiometer W produces the low level signal of telecommunication, on the contrary, the triggering signal of monostable flipflop output high level.

With reference to Fig. 4, in the present embodiment, temperature detecting module is single-shot trigger circuit, when thermo-sensitive resistor RT place ambient temperature is higher, the resistance of thermo-sensitive resistor RT reduces, common node in thermo-sensitive resistor RT and potentiometer W produces the low level signal of telecommunication, on the contrary, the triggering signal of monostable flipflop output high level.

With reference to Fig. 5, the control module 300 in the present embodiment includes AND circuit and processor, and wherein processor is AT89C51 system.

Wherein, the first outfan and second outfan of AT89C51 system is respectively used to export DIR signal and pwm signal.

With reference to Fig. 6, control module 300 also includes that reversing unit 320, reversing unit 320 include not circuit U3A, AND circuit U4A and AND circuit U4B.

The input of not circuit U3A is coupled to the first outfan of AT89C51 system, and outfan is coupled to an input of AND circuit U4A, and input and outfan at not circuit U3A produce signal DIR-A and signal DIR-B respectively；Another input of AND circuit U4A is coupled to the second outfan of AT89C51 system, and the outfan of AND circuit U4A is used for output signal PWM-A；One input of AND circuit U4B is coupled to the first outfan of AT89C51 system, and another input is coupled to the second outfan of AT89C51 system, and outfan is used for output signal PWM-B.

Reversing unit 320 in Fig. 6 works as follows:

Signal DIR-A through not circuit U3A reversely after with signal PWM and computing after output signal PWM-A, synchronous signal DIR-A and signal PWM output signal PWM-B directly and after computing, due to not circuit U3A back action, signal PWM-A and signal PWM-B Zong You mono-tunnel is made to be output as 0, wherein signal DIR-A(signal DIR) it is the motor steering control signal of AT89C51 system output.

With reference to Fig. 7, the driving module 400 in the present embodiment includes H-bridge drive circuit, the first control portion and the second control portion.

Wherein, H-bridge drive circuit concrete introduce can chapter 2 in Master's thesis " design studies of H bridge power driving circuit ", the present embodiment is regarded it as the known technology of those skilled in the art, is therefore repeated no more.It should be noted that on H bridge, brachium pontis is made up of switching device Q3 and switching device Q7, under H bridge, brachium pontis is made up of switching device Q4 and switching device Q8, and the control pole closing device Q4 receives signal PWM-A, and the control pole closing device Q8 receives signal PWM-B.

Wherein, the first control portion includes that audion Q1, the base stage of audion Q1 are used for receiving signal DIR-A, and its colelctor electrode is coupled to the control pole of one of them switching device Q3 of brachium pontis on H bridge, its grounded emitter.

Wherein, the second control portion includes that audion Q11, the base stage of audion Q11 are used for receiving signal DIR-B, and its colelctor electrode is coupled to the control pole of the other in which switching device Q7 of brachium pontis on H bridge, its grounded emitter.

Driving module 400 in Fig. 7 works as follows:

Signal DIR-A controls opening and turning off of switching device Q3 by audion Q1, the switching device Q3 conducting when DIR-A is 1, owing to the state of signal DIR-A makes signal PWM-A be 0, signal PWM-B is effective, signal DIR-B is reverse with signal DIR-A, signal DIR-B is 0, and now switching device Q7 turns off.Only need control signal PWM-B to motor, realization can be carried out speed governing.If defining now, motor is for rotating forward, and when signal DIR-A is 0, switching device Q3 turns off, and switching device Q7 turns on, and signal PWM-A is effective, and signal PWM-B is 0, now motor reversal.

Wherein, register is set at hollow sandwich, the air in curtain wall intermediate layer is freezed or heats, thus form one layer of heat preservation layer, make the temperature relative constancy of building inside curtain wall, do not affected by ambient temperature, reach the effect of constant temperature, to sum up, reach the energy-saving effect of 80%.

The above is only preferred implementation of the present utility model, and protection domain of the present utility model is not limited merely to above-described embodiment, and all technical schemes belonged under this utility model thinking belong to protection domain of the present utility model.It should be pointed out that, for those skilled in the art, without departing from the some improvements and modifications under this utility model principle premise, these improvements and modifications also should be regarded as protection domain of the present utility model.

Claims (10)

1. an automatic wind induction type constant temperature curtain wall system, including inner layer glass (1) and glass outer (2), there is between described inner layer glass (1) and glass outer (2) hollow sandwich (3), it is characterized in that: described hollow sandwich (3) passes through shutter (4) and ft connection, described shutter (4) is driven by motor, the outside of described glass outer (2) is provided with wind-force detection module (100) and temperature detecting module (200), the outside of described inner layer glass (1) is provided with control module (300) and drives module (400),

Described wind-force detection module (100) exports wind-force detection signal when outdoor wind-force exceedes setting value；

Described temperature detecting module (200) is output temperature detection signal when outside humidity exceedes setting value；

Output control signal when described control module (300) receives wind-force detection signal and temperature detection signal at the same time；

Described driving module (400) drives motor to open shutter (4) in response to control signal.

Automatic wind induction type constant temperature curtain wall system the most according to claim 1, it is characterised in that: described control module (300) includes AND circuit and processor (310),

Wind-force is detected signal and temperature detection signal and exports to AND circuit by wind-force detection module (100) and temperature detecting module (200) respectively, and the outfan of AND circuit is connected to processor (310)；

Processor (310) controls pwm signal and the DIR signal of control motor steering of electric machine rotation according to AND circuit to the operation result output of wind-force detection signal and temperature detection signal.

Automatic wind induction type constant temperature curtain wall system the most according to claim 2, it is characterized in that: described control module (300) also includes reversing unit (320), it is in the DIR-A signal of DIR signal and anti-phase in the DIR-B signal of DIR signal that DIR signal is converted into a homophase by described reversing unit (320)；

Described driving module (400) is H bridge, receives DIR-A signal and DIR-B signal control motor rotates.

Automatic wind induction type constant temperature curtain wall system the most according to claim 3, it is characterised in that: it is coupled with fuse-link between common port and the power supply of described two brachium pontis of H bridge.

Automatic wind induction type constant temperature curtain wall system the most according to claim 1, it is characterised in that: described wind-force detection module (100) includes single-shot trigger circuit, and the triggering signal of described single-shot trigger circuit is provided by resistance strain gage.

Automatic wind induction type constant temperature curtain wall system the most according to claim 5, it is characterised in that: the resistance of described resistance strain gage increases with pressure and reduces, and provides to single-shot trigger circuit and triggers signal.

Automatic wind induction type constant temperature curtain wall system the most according to claim 5, it is characterised in that: the outfan of described single-shot trigger circuit connects display lamp.

Automatic wind induction type constant temperature curtain wall system the most according to claim 1, it is characterised in that: described temperature detecting module (200) includes single-shot trigger circuit, and the triggering signal of described single-shot trigger circuit is provided by humistor.

Automatic wind induction type constant temperature curtain wall system the most according to claim 8, it is characterised in that: the resistance of described humistor increases with suffered ambient humidity and reduces, and provides to single-shot trigger circuit and triggers signal.

Automatic wind induction type constant temperature curtain wall system the most according to claim 8, it is characterised in that: the outfan of described single-shot trigger circuit connects display lamp.