CN217521506U - Intelligent household adjusting system based on power generation glass - Google Patents

Abstract

The utility model discloses an intelligent household regulating system based on power generation glass, which comprises self-generating electrochromic glass, a control module, a data acquisition module, a data transmission module, a power supply module, a cloud server and a mobile terminal, wherein the self-generating electrochromic glass, the data acquisition module, the data transmission module are connected with the control module, the cloud server is connected with the control module through the data transmission module, the mobile terminal is connected with the cloud server, the control module is connected with the power supply module, the self-generating electrochromic glass is effectively combined with an intelligent circuit, light energy is absorbed and converted into electric energy which is stored in a storage battery of the power supply module, the power supply module supplies power to the control module, the control module receives and processes environmental data acquired by the data acquisition module and transmits the environmental data to the mobile terminal, and a user can remotely control the electric appliance in a room through the cloud server on the mobile terminal to obtain the working state and the color change and light of the electrochromic glass, the intelligent home system is convenient to adjust, and meanwhile, the energy-saving effect is achieved.

Description

Intelligent household adjusting system based on power generation glass

Technical Field

The utility model belongs to the technical field of intelligent house, especially, relate to an intelligent house governing system based on electricity generation glass.

Background

The electrochromic device has wider application in the fields of buildings, vehicles, intelligent furniture and military instruments, for example, the electrochromic device is applied to electrochromic glass, the existing electrochromic glass has good color-changing performance and good ultraviolet light absorption performance and occupies a certain share in the market, and the electrochromic technology generally comprises the steps of merging the positive electrode and the negative electrode of the glass into a circuit, and applying working voltage to the two ends of the glass through an additional circuit to enable materials in the glass to generate redox reaction to complete color change. Generally, the limitation of the internal material selection of the glass and the limitation of single function of a control system cause the phenomena of nonuniform color change, slow color change, difficult quick response and the like in production and practical application.

At present, the electrochromic technology mainly comprises electric control liquid crystal color change, solid film electrochromic color change, organic dye color change and the like, and the electric control liquid crystal color change technology needs to be supplied with power continuously and consumes huge energy; the solid film electrochromic technology has higher cost and poor color development effect; the organic dye color-changing technology is easy to decompose under strong light and is difficult to apply in a real scene. Because the development time of the intelligent glass dimming system is short, the electrochromic glass applied to the intelligent color-changing dimming glass system has no control effect, and the simple control system cannot meet the complex intelligent household requirement.

SUMMERY OF THE UTILITY MODEL

To the problem, the utility model provides an intelligence house governing system based on electricity generation glass through effectively fusing multisource sensor and the electricity generation glass that discolours and intelligent circuit, reaches multi-functionalization, low-power consumption and convenient intelligent home systems.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides an intelligent home furnishing adjusting system based on power generation glass, which comprises self-power generation electrochromic glass, a control module, a data acquisition module, a data transmission module, a power supply module, a cloud server and a mobile terminal, wherein the self-power generation electrochromic glass, the data acquisition module, the data transmission module are connected with the control module, the cloud server is connected with the control module through the data transmission module, the mobile terminal is connected with the cloud server, and the control module is connected with the power supply module;

the self-generating electrochromic glass comprises hard sandwich glass, a layer of toughened glass and a layer of ITO conductive glass, and double-metal-based electrochromic gel is filled between the toughened glass and the ITO conductive glass, the self-generating electrochromic glass is installed on a window of a room, the control module is used for connecting a circuit of the self-generating electrochromic glass, and the circuit is accommodated in a frame of the self-generating electrochromic glass and connected with the power supply module;

the self-generating electrochromic glass absorbs light energy and converts the light energy into electric energy to be stored in the power supply module, the power supply module supplies power to the control module, the control module receives and processes environmental data in a collected room sent by the data collection module and integrates and sends the environmental data to the mobile terminal, and the mobile terminal remotely controls the working states of the self-generating electrochromic glass and electrical appliances in the room through the cloud server.

As a further improvement of the above technical solution, a digital temperature sensor of the data acquisition module, the model of which is TMP1075, is denoted as U2, pins a0, a1 and a2 of the digital temperature sensor are grounded to set an I2C communication address of the chip U2, pins SDA and SCL of the U2 chip are used to connect a data line and a clock line, respectively, and are connected to the control module, a ALERT pin of the chip U2 controls a measurement time of the TMP1075, and the pins SDA and SCL are connected to the capacitor C7 and the capacitor C6, respectively, to realize level pull-up of SDA, SCL and ALERT.

As a further improvement of the above technical solution, the control module includes a chip model M5311, which is denoted as U1, a RESET switch, an ON/OFF switch and a TVS diode, the RESET switch, the ON/OFF switch and the TVS diode are connected in parallel to the chip U1, IIC _ SDA and IIC _ SCL of the chip U1 are I2C bus communication serial ports and perform data transmission with the data acquisition module, and the first LED lamp at the STATE port of the U1 chip is used for reflecting the operating STATE of the chip U1.

As a further improvement of the above technical solution, the models of the ON/OFF switch and the RESET switch are both K2-3.6 multiplied by 6.1_ SMD, the model of the TVS diode is SMBJ8.0A _ C39709, and the model of the LED lamp is LED-0603_ G.

As a further improvement of the above technical solution, the operation modes of the control module include start and RESET, when the chip U1 is turned OFF, the ON/OFF switch of the chip U1 is pressed for at least two seconds to turn ON, when the chip U1 is turned ON, the chip U1 is turned OFF for at least eight seconds, and when the chip U1 is operated, the RESET switch is pressed to RESET.

As a further improvement of the above technical solution, the DATA transmission module is a SIM card connector, and the SIM card connector includes a SIM _ RST pin, a SIM _ CLK pin, a SIM _ DATA pin, a SIM _ VCC pin, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor C5, a diode D7, a diode D8, a diode D9, and a diode D10;

the capacitor C3, the capacitor C4 and the capacitor C5 are connected in parallel and respectively connected with the SIM _ RST pin, the SIM _ DATA pin and the SIM _ CLK pin, the diode D8, the diode D9 and the diode D10 are connected in parallel and respectively connected with the SIM _ RST pin, the SIM _ DATA pin and the SIM _ CLK pin, the diode D7 and the capacitor C2 are connected with the SIM _ VCC pin, the diode D7, the diode D8, the diode D9 and the diode D10 are used for circuit protection of the DATA transmission module, and the capacitor C3, the capacitor C4 and the capacitor C5 are used for stabilizing serial port voltage variation of the SIM card connector.

As a further improvement of the above technical solution, the SIM _ RST pin is a reset pin, the SIM _ CLK pin is a clock pin, the SIM _ DATA pin is a DATA pin, and the SIM _ VCC pin is a power supply pin for the SIM card.

As a further improvement of the technical scheme, the model of the SIM card connector is SIM-002-A6.

As a further improvement of the above technical solution, the self-generating electrochromic glass is adhered to a first frame and a second frame of a window, lines in the first frame are gathered in the second frame and extend to a main circuit on the lower side of the self-generating electrochromic glass, and excess electric energy in the lines is stored in the power supply module, wherein the frame includes the first frame and the second frame, and the first frame and the second frame are vertically arranged.

The utility model provides an intelligence house governing system based on electricity generation glass for prior art, has following beneficial effect:

1) through effectively combining self-generating electrochromic glass and intelligent circuit, can absorb light energy and turn into the electric energy and store in power module's battery, power module supplies power for control module, control module receives and handles data acquisition module collection environmental data and send to mobile terminal, but the user gets operating condition and electrochromic glass's with electrical apparatus discoloration light modulation in the remote control room through cloud ware on mobile terminal, it is more convenient to make intelligent home systems adjust, also reach energy-conserving effect simultaneously.

2) The utility model discloses still for absorbing ultraviolet radiation's transparent photovoltaic cell and high performance large tracts of land electrochromic glass, through integrated photovoltaic cell layer and photochromic glass layer, can increase built-in high specific energy lithium ion energy storage battery and realize integration energy collection, add intelligent circuit according to the actual demand, combine intelligent perception and manual discolour, add based on the long-range regulation and control device of thing networking like mobile terminal, satisfy many scene demands. And integrating the transparent photovoltaic cell, the electrochromic glass, the energy storage element and the intelligent control circuit. The double-metal-base electrolyte gel is used as a color changing layer, has the characteristics of high reaction speed, wide visible light adjusting range and high cycle stability, can realize continuous self-adaptive dimming, and keeps fading and coloring bistable state cycle, thereby achieving the effects of preventing glare and peep, adjusting indoor light and temperature, and simultaneously reducing heat dissipation.

3) The system realizes the internal communication of the electrochromic glass, the transparent photovoltaic cell and the control circuit under the condition of meeting the requirement of automatically adjusting the color of the glass, forms an energy acquisition closed-loop control system, applies the remote regulation and control system of the Internet of things to the intelligent glass color-changing system, meets the requirement of combining intelligent perception and manual color change, and realizes the remote adjustment and intelligent application of the intelligent glass.

Drawings

Fig. 1 is a structural block diagram of the smart home adjusting system based on the power generation glass of the present invention;

fig. 2 is a circuit diagram of the data acquisition module of the present invention;

fig. 3 is a circuit diagram of the control module of the present invention;

fig. 4 is a circuit diagram of the data transmission module of the present invention;

fig. 5 is a schematic structural diagram of the self-generating electrochromic glass of the present invention.

The main element symbols are as follows:

100-self-generating electrochromic glass; 110-a control module; 120-a data acquisition module; 130-a data transmission module; 140-a power supply module; 150-a cloud server; 160-mobile terminal; 170-a first frame; 180-a second frame; 190-main circuit.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Referring to fig. 1, the utility model provides an intelligent house governing system based on electricity generation glass, including spontaneous electricity generation electrochromic glass 100, control module 110, data acquisition module 120, data transmission module 130, power module 140, cloud server 150 and mobile terminal 160, spontaneous electricity generation electrochromic glass 100, data acquisition module 120, data transmission module 130 with control module 110 is connected, cloud server 150 with control module 110 passes through data transmission module 130 and is connected, mobile terminal 160 with cloud server 150 is connected, control module 110 with power module 140 is connected;

the self-generating electrochromic glass 100 comprises hard sandwich glass, a layer of toughened glass and a layer of ITO conductive glass, and double-metal-based electrochromic gel is filled between the toughened glass and the ITO conductive glass, the self-generating electrochromic glass 100 is installed on a window of a room, the control module 110 is used for connecting a circuit of the self-generating electrochromic glass 100, and the circuit is accommodated in a frame of the self-generating electrochromic glass 100 and is connected with the power supply module 140;

the self-generating electrochromic glass 100 absorbs light energy and converts the light energy into electric energy to be stored in the power supply module 140, the power supply module 140 supplies power to the control module 110, the control module 110 receives and processes environmental data in a collection room sent by the data collection module 120 and integrates and sends the environmental data to the mobile terminal 160, and the mobile terminal 160 remotely controls the working states of the self-generating electrochromic glass 100 and electrical appliances in the room through the cloud server 150.

In this embodiment, the self-generating electrochromic glass 100 is a hard laminated glass, and a primary battery is formed by filling a bimetal electrochromic gel between a layer of toughened glass and a layer of ITO conductive glass, and the color change is completed through an oxidation-reduction reaction. The packaging process of the glass is the same as that of the common double-layer vacuum-pumping heat-insulating glass, and the gel of the glass is ensured not to leak. The power supply module can be a high specific energy lithium ion energy storage battery arranged near the color-changing glass, the power generation glass can absorb ultraviolet rays and convert light energy into electric energy to be stored in a storage battery of the power supply module 140, and certain electric power support is provided for glass color changing or other electric appliances under the condition of dark light. The data acquisition module 120 is realized through various environmental perception sensors, and environmental data includes temperature and humidity sensor, fire alarm ware etc. and various sensors collect multidimension degree information, build the multinary database, use high in the clouds new algorithm high efficiency processing data. The cloud server 150 is responsible for receiving and processing the data collected by the data collection module 120, and uploading the data to the mobile terminal 160, so that the user can check the indoor conditions in real time. Can receive the instruction from the user side simultaneously and convey to the glass end that discolours, remote control discolours, or presets the outage time at the removal end, sends the instruction to electrical apparatus end by the high in the clouds is on its own, realizes intelligent control's effect.

It should be noted that, in the system, the self-generating electrochromic glass 100 has the characteristics of being monolithic, easy to replace and install, so that the component can be replaced by filling different materials to replace the materials used in the electrolyte gel used in the electrochromic glass, and the replaceable materials include transition metal oxides, composite metal oxides, other inorganic materials such as prussian blue and the like with electrochromic characteristics, or organic materials such as metal organic chelates and conductive polymers, and in combination with different electrolyte gels, the electrochromic glass can realize different color changes.

It should be understood that in the data transmission, data between the environmental awareness sensor and the cloud server 150 may be transmitted through the reader and the gateway node by using a wireless communication connection, and the cloud server 150 and the mobile terminal 160 are connected through a protocol. The electrical appliance can be color-changing glass, or an indoor lamp, a table lamp and the like, the electrochromic glass absorbs light energy and converts the light energy into electric energy to be stored in the high-specific-energy storage battery of the power supply module 140, the power supply module 140 supplies power to the control module 110, and the control module 110 receives and processes signals from the environment sensing sensor and integrates information to send the information to the mobile terminal 160. The user can remotely control electrical appliances in the room, including electrochromic glass, at the mobile terminal 160, so that the intelligent home adjustment system can save energy and has low power consumption compared with the existing control system in the market.

Referring to fig. 2, a digital temperature sensor of the data acquisition module 120 with a model of TMP1075 is denoted as U2, pins a0, a1 and a2 of the digital temperature sensor are grounded to set an I2C communication address of the chip U2, pins SDA and SCL of the U2 chip are used to connect a data line and a clock line, respectively, and are connected to the control module, a terminal ALERT of the chip U2 controls a measurement time of the TMP1075, and pins SDA and SCL are connected to a capacitor C7 and a capacitor C6, respectively, to achieve level pull-up of SDA, SCL and ALERT.

In this embodiment, the I2C bus is a standard bi-directional interface that uses a controller, i.e., master controller, to communicate with slaves that cannot transfer data unless they have been addressed by the master, each device on the I2C bus has a specific device address to distinguish between other devices on the same I2C bus. The physical I2C interface consists of a Serial Clock (SCL) and Serial Data (SDA) line. Both the SDA and SCL lines must be connected to VCC through a pull-up resistor, the size of which is determined by the amount of capacitance on the I2C line. Data transfer can only be initiated when the bus is idle, and the bus is considered idle if both the SDA and SCL lines are high after a stop condition.

It should be noted that the TMP1075 chip has the characteristics of high sensitivity and strong customization capability, and its pins a0, a1, a2 are grounded, and its I2C communication address is set. SDA and SCL are I2C bus data line and clock line, and can carry out data transmission with the master control chip. The ALERT pin controls the measurement time of the TMP1075, and three ports of the SDA, the SCL and the ALERT need to realize level pull-up, so a pull-up circuit and a protection capacitor are arranged outside the ports. Temperature information can be transmitted to a main control chip through an I2C bus to realize real-time temperature measurement, and the I2C bus communication technology can realize a one-master multi-slave device connection mode, and only needs to set relative addresses of devices, namely, more digital sensors can be expanded to realize sensing of more information besides the sensor provided in the embodiment.

Referring to fig. 3, the control module 110 includes a chip model M5311, which is denoted as U1, a RESET switch, an ON/OFF switch, and a TVS diode, the RESET switch, the ON/OFF switch, and the TVS diode are connected in parallel to the chip U1, IIC _ SDA and IIC _ SCL of the chip U1 are I2C bus communication serial ports and perform data transmission with the data acquisition module, and a first LED lamp at the STATE port of the U1 chip is used to reflect the operating STATE of the chip U1.

In this embodiment, the ON/OFF switch and the RESET switch are both in the type of K2-3.6 × 6.1_ SMD, the TVS diode is in the type of SMBJ8.0A _ C39709, and the LED lamp is in the type of LED-0603_ G. The working modes of the control module comprise starting and resetting, when the chip U1 is powered OFF, the chip U1 is powered ON for at least two seconds by pressing the ON/OFF switch, the chip U1 is powered OFF for at least eight seconds by the power-ON duration of the chip U1, and when the chip U1 runs, the RESET switch is pressed for resetting.

It should be noted that, the control module adopts a middle mobile M5311 chip, and the chip can realize the OPENCPU function on the basis of realizing the transmission of the narrowband internet of things, and has the functions of data acquisition and data transmission. IIC _ SDA and IIC _ SCL are I2C bus communication serial ports, and information communication with the sensors is achieved. And the LED lamp at the STATE port reflects the working STATE of the chip. The chip has starting and resetting functions, when the chip is shut down, the chip is started for more than 2 seconds by pressing the ON/OFF switch for a long time, when the chip is started, the chip is shut down by pressing the ON/OFF switch for more than 8 seconds, and when the chip runs, the RESET switch is pressed for resetting. In the figure, the TVS diode plays an ESD protection role, namely electrostatic protection, and the working stability of the control module is improved.

Referring to fig. 4, the DATA transmission module 130 is a SIM card connector, which includes a SIM _ RST pin, a SIM _ CLK pin, a SIM _ DATA pin, a SIM _ VCC pin, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor C5, a diode D7, a diode D8, a diode D9, and a diode D10; the capacitor C3, the capacitor C4 and the capacitor C5 are connected in parallel and are respectively connected with the SIM _ RST pin, the SIM _ DATA pin and the SIM _ CLK pin, the diode D8, the diode D9 and the diode D10 are connected in parallel and are respectively connected with the SIM _ RST pin, the SIM _ DATA pin and the SIM _ CLK pin, the diode D7 and the capacitor C2 are connected with the SIM _ VCC pin, the diode D7, the diode D8, the diode D9 and the diode D10 are used for circuit protection of the DATA transmission module, and the capacitor C3, the capacitor C4 and the capacitor C5 are used for stabilizing serial port voltage changes of the SIM card connector.

In this embodiment, the SIM _ RST pin is a reset pin, the SIM _ CLK pin is a clock pin, the SIM _ DATA pin is a DATA pin, the SIM _ VCC pin is a power supply pin for the SIM card, and the SIM card connector is of the type SIM-002-a 6. D7 plays the guard action to D10 diode, and the serial port voltage change is stabilized to C3 to C5 condenser, and M5311 utilizes SIM card connector to insert mobile internet, and the data transmission that will gather the sensor is to cloud ware, realizes handling on the data cloud, and the data is conveyed to mobile terminal through cloud ware again.

Referring to fig. 5, the self-generating electrochromic glass 100 is adhered to a first frame 170 and a second frame 180 of a window, lines in the first frame 170 are gathered in the second frame 180 and extend to a main circuit 190 on the lower side of the self-generating electrochromic glass 100, and excess electric energy in the lines is stored in the power supply module 140, wherein the frames include the first frame 170 and the second frame 180, and the first frame 170 and the second frame 180 are vertically arranged.

In the embodiment, the circuit is fixedly installed in the first frame of the glass around the self-generating electrochromic glass, the first frame and the second frame are fixed and adhered by glue and cannot be detached, when the self-generating electrochromic glass is maintained or replaced, one piece of glass and the frames on four sides are taken as the minimum unit, the circuit in the first frame is gathered in the second frame on the periphery, and finally the circuit is connected to the main circuit in the lower side of the glass, and redundant electric energy is stored in the power supply module embedded in the window. The transparent photovoltaic cell, namely the photosensitive material of the power generation glass, is prepared from an organic-inorganic hybrid lead-calcium-titanium chloride ore material with a wide band gap, has strong absorption capacity on ultraviolet radiation, and converts the ultraviolet radiation into electric energy while ensuring high visible light transmittance, thereby realizing the dual requirements of energy conservation, environmental protection and healthy life.

It should be noted that, the bi-metal-based electrolyte gel is adopted as the color-changing layer, so that the method has the characteristics of high reaction speed, wide visible light adjusting range and high cycle stability, and can realize continuous self-adaptive light adjustment and keep the color-changing and coloring bi-stable cycle. The effects of preventing glare and peep, adjusting indoor light and temperature and reducing heat dissipation are achieved. Under the condition that the integrated intelligent control system meets the requirement of automatically adjusting the color of the glass, the internal communication of the electrochromic glass, the transparent photovoltaic cell and the control circuit is realized, and an energy acquisition closed-loop control system is formed. The remote regulation and control system of the Internet of things is applied to the intelligent glass color changing system, intelligent sensing and manual color changing combination are met, and remote regulation and intelligent application of intelligent glass are achieved.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (9)

1. The intelligent home furnishing adjusting system based on the power generation glass is characterized by comprising self-generating electrochromic glass, a control module, a data acquisition module, a data transmission module, a power supply module, a cloud server and a mobile terminal, wherein the self-generating electrochromic glass, the data acquisition module and the data transmission module are connected with the control module, the cloud server is connected with the control module through the data transmission module, the mobile terminal is connected with the cloud server, and the control module is connected with the power supply module;

the self-generating electrochromic glass comprises hard sandwich glass, a layer of toughened glass and a layer of ITO conductive glass, and double-metal-based electrochromic gel is filled between the toughened glass and the ITO conductive glass, the self-generating electrochromic glass is installed on a window of a room, the control module is used for connecting a circuit of the self-generating electrochromic glass, and the circuit is accommodated in a frame of the self-generating electrochromic glass and connected with the power supply module;

the self-generating electrochromic glass absorbs light energy and converts the light energy into electric energy to be stored in the power supply module, the power supply module supplies power to the control module, the control module receives and processes environmental data in a collection room sent by the data collection module and integrates and sends the environmental data to the mobile terminal, and the mobile terminal remotely controls the working states of the self-generating electrochromic glass and electrical appliances in the room through the cloud server.

2. The intelligent household adjusting system based on power generation glass as claimed in claim 1, wherein the digital temperature sensor of the data acquisition module with model number TMP1075 is marked as U2, pins A0, A1 and A2 of the digital temperature sensor are grounded to set the I2C communication address of the chip U2, pins SDA and SCL of the U2 chip are used for connecting a data line and a clock line respectively and are connected to the control module, a pin ALERT of the chip U2 controls the measurement time of the TMP1075, and the pins SDA and SCL are connected with a capacitor C7 and a capacitor C6 respectively to realize the level pull-up of SDA, SCL and ALERT.

3. The intelligent household regulating system based ON the power generation glass as claimed in claim 1, wherein the control module comprises a model M5311 chip, which is marked as U1, a RESET switch, an ON/OFF switch and a TVS diode, the RESET switch, the ON/OFF switch and the TVS diode are connected in parallel to a chip U1, IIC _ SDA and IIC _ SCL of the chip U1 are I2C bus communication serial ports and perform data transmission with the data acquisition module, and an LED lamp at a STATE port of the U1 chip is used for reflecting the working STATE of the chip U1.

4. The smart home conditioning system based ON power generating glass according to claim 3, wherein the ON/OFF switch and the RESET switch are both of type K2-3.6 x 6.1_ SMD, the TVS diode is of type SMBJ8.0A _ C39709, and the LED lamp is of type LED-0603_ G.

5. The smart home conditioning system based ON power generation glass according to claim 3, wherein the operation modes of the control module comprise startup and RESET, when the chip U1 is turned OFF, the chip U1 is turned ON for at least two seconds by pressing the ON/OFF switch, when the chip U1 is turned ON, the chip U1 is turned OFF for at least eight seconds, and when the chip U1 is operated, the RESET switch is pressed for resetting.

6. The smart home conditioning system based on power generating glass according to claim 1, wherein the DATA transmission module is a SIM card connector, the SIM card connector comprising a SIM _ RST pin, a SIM _ CLK pin, a SIM _ DATA pin, a SIM _ VCC pin, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor C5, a diode D7, a diode D8, a diode D9, and a diode D10;

the capacitor C3, the capacitor C4 and the capacitor C5 are connected in parallel and respectively connected with the SIM _ RST pin, the SIM _ DATA pin and the SIM _ CLK pin, the diode D8, the diode D9 and the diode D10 are connected in parallel and respectively connected with the SIM _ RST pin, the SIM _ DATA pin and the SIM _ CLK pin, the diode D7 and the capacitor C2 are connected with the SIM _ VCC pin, the diode D7, the diode D8, the diode D9 and the diode D10 are used for circuit protection of the DATA transmission module, and the capacitor C3, the capacitor C4 and the capacitor C5 are used for stabilizing serial port voltage variation of the SIM card connector.

7. The smart home conditioning system based on power generating glass according to claim 6, wherein the SIM _ RST pin is a reset pin, the SIM _ CLK pin is a clock pin, the SIM _ DATA pin is a DATA pin, and the SIM _ VCC pin is a SIM card power supply pin.

8. The smart home conditioning system based on power generating glass according to claim 6, wherein the SIM card connector is SIM-002-A6.

9. The smart home conditioning system based on power generating glass according to claim 1, wherein the self-generating electrochromic glass is adhered to a first frame and a second frame of a window, lines in the first frame are gathered in the second frame and extend to a main circuit on the lower side of the self-generating electrochromic glass, and redundant electric energy in the lines is stored to the power supply module, wherein the frames comprise the first frame and the second frame, and the first frame and the second frame are vertically arranged.

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