TWM613916U - Intelligent electronic sunblind control system - Google Patents

Abstract

An intelligent electronic sunblind control system includes a control equipment, a monitoring equipment, a sensing equipment, a sunblind equipment, a lighting equipment, and an air conditioning equipment. The control equipment is respectively coupled to the monitoring equipment, the sensing equipment, the sunblind equipment, the lighting equipment, and the air conditioning equipment. The monitoring equipment can capture indoor images, and the sensing equipment can sense outdoor luminance. The control equipment is configured to obtain different indoor luminance values according to indoor images captured by the monitoring equipment under different indoor luminance, and to compare the indoor luminance value with the outdoor luminance value sensed by the sensing equipment to determine the degree of opening of the sunblind equipment, the brightness of the lighting equipment, and the setting of the air conditioning equipment.

Description

Electric curtain intelligent control system

The model relates to a control system, especially an intelligent control system for electric curtains.

With the advancement of technology and the improvement of living standards, smart curtains have emerged to meet people's requirements for smart homes. However, the current smart curtains usually only control the opening and closing actions of the curtains through a remote control, and the control method is single and simple, which cannot meet people's requirements for smart homes. Therefore, there is a smart curtain with an indoor illuminance meter to obtain the indoor illuminance through the indoor illuminance meter to control the opening and closing of the curtain. However, smart curtains combined with traditional indoor illuminance meters have only one lighting spot, which is easily affected by sunlight, lamps, and neighboring lamps, which can cause problems such as unstable control and make the user experience unable to be improved.

Therefore, the inventor of the present invention feels that the above shortcomings can be improved, and has made great efforts to research and cooperate with the application of theories, and finally proposes a reasonable design and effective improvement of the above shortcomings of this new model.

The technical problem to be solved by the present invention is to provide an electric curtain intelligent control system in view of the shortcomings of the prior art.

In order to solve the above technical problems, the present invention provides an electric curtain intelligent control system, including: control equipment, monitoring equipment, sensing equipment, curtain equipment, lighting equipment, and air conditioning equipment, and the control equipment is respectively coupled to the monitoring equipment, The sensing device, the curtain device, the lighting device, and the air conditioning device; wherein the monitoring device can shoot indoor images, the sensing device can sense outdoor illuminance, and the control device is configured to operate according to the monitoring device The different indoor illuminance values obtained from indoor images shot under different indoor illuminances are compared with the outdoor illuminance values sensed by the sensing device to determine the curtain opening of the curtain device, determine the brightness of the lighting device, and determine The air conditioning settings of the air conditioning equipment.

Preferably, the monitoring device is a camera, which is coupled to the control device.

Preferably, the sensing device includes an outdoor illuminance sensor coupled to the control device.

Preferably, the sensing device further includes an outdoor temperature and humidity sensor, a wind speed and direction detector, a rainfall detector, an indoor temperature and humidity sensor, and a device power detector, respectively coupled to The control equipment.

Preferably, the control device is further configured to obtain the sunlight direction according to the indoor images taken under different sunlight shadows generated by the monitoring device in different sunlight directions, and the control device is further configured to obtain the solar longitude and latitude of the current area to The sun position is obtained, and the control device further determines the curtain opening of the curtain device, determines the lighting brightness of the lighting device, and determines the air conditioning setting of the air conditioner based on the sunlight direction and the sun position.

Preferably, the control device includes an application interface, a central processing unit, a data storage unit, and a communication unit, and the central processing unit is respectively coupled to the application interface, the data storage unit, and the communication unit.

Preferably, the application interface contains a graphical analysis interface, and the graphical analysis interface further includes a user setting module, an analysis module, and a storage and output module. The user setting module is configured for the user to set. The analysis module is configured to perform graphical analysis, and the storage and output module is configured to store and output analysis results.

Preferably, the application interface further includes a man-machine interface, and the man-machine interface further includes a user interface setting module, a control module, and a recording and output module. The user interface setting module is configured for the user to perform The interface settings and the control module configuration are used to execute self-defined process control, automatic scheduling control, and automatic day tracking control, and the recording and output module configuration is used to generate and output records.

Preferably, the control module includes a self-defined process control module, the self-defined process control module includes a self-defined temperature control module, and the self-defined temperature control module is configured to perform the steps of the self-defined temperature control , Including: obtaining a sensing parameter; calculating the average value of the obtained sensing parameter in a period of time, and the average value of the sensing parameter in the period includes the average value of outdoor temperature and humidity parameters and the average value of indoor temperature and humidity; Compare the average value of the outdoor temperature and humidity parameters with the average value of the indoor temperature and humidity to obtain a comparison result; substitute comfort parameters; and determine the air conditioning setting and the curtain opening degree according to the comparison results and the comfort parameters.

Preferably, the control module includes a self-defined process control module, the self-defined process control module includes a self-defined energy-saving control module, and the self-defined energy-saving control module is configured to execute the steps of the self-defined energy-saving control , Including: obtaining a sensing parameter; calculating the average value of the obtained sensing parameter in a period of time. The average value of the sensing parameter in the period includes the average value of indoor temperature and humidity, the average value of outdoor temperature and humidity, and the average value of indoor temperature and humidity. The average value of the illuminance and the average value of the outdoor illuminance; compare the average value of the indoor temperature and humidity, the average value of the outdoor temperature and humidity, the average value of the indoor illuminance, and the average value of the outdoor illuminance to obtain a comparison result; Compare the results to determine the air conditioning settings, determine the brightness of the lighting, and determine the opening of the curtains.

Preferably, the control module includes an automatic scheduling control module configured to perform the steps of automatic scheduling control, including: obtaining the current time; checking the scheduling time; according to the schedule Time is used to determine the opening of the curtains, the brightness of the lighting, and the air conditioning settings.

Preferably, the control module includes an automatic sun tracking control module, and the automatic sun tracking control module is configured to perform the steps of automatic sun tracking control, including: obtaining the direction of sunlight; obtaining the latitude and longitude of the sun; and obtaining sensing parameters; Calculate the obtained average value of the sensing parameter in a period of time, the average value of the sensing parameter in the period includes the average value of outdoor illuminance and the average value of indoor illuminance; compare the average value of outdoor illuminance and the indoor illuminance The average value of, obtain a comparison result; substitute the comfort parameter; according to the comparison result and the comfort parameter, determine the curtain opening, determine the lighting brightness, and determine the air conditioning settings.

The beneficial effect of the present invention is at least that the electric curtain intelligent control system provided by the present invention can shoot indoor illuminance images through monitoring equipment, the sensing equipment can sense outdoor illuminance, and the control equipment can shoot under different indoor illuminances according to the monitoring equipment The different indoor illuminance values obtained from the indoor image of the camera are compared with the outdoor illuminance values sensed by the sensing device to determine the curtain opening of the curtain device, the brightness of the lighting device, and the air-conditioning setting of the air-conditioning device. It can intelligently control the curtain opening, lighting brightness, and air conditioning settings according to the indoor and outdoor lighting conditions, so as to achieve the best intelligent control and enhance the user experience.

In order to further understand the features and technical content of the present invention, please refer to the following detailed descriptions and drawings about the present invention. However, the drawings provided are only for reference and explanation, and are not used to limit the present invention.

The following are specific specific examples to illustrate the related implementations disclosed in the present invention. Those skilled in the art can understand the advantages and effects of the present invention from the contents disclosed in this specification. The present invention can be implemented or applied through other different specific embodiments. Various details in this specification can also be based on different viewpoints and applications, and various modifications and changes can be made without departing from the concept of the present invention. In addition, the drawings of the present invention are merely schematic illustrations, and are not drawn according to actual dimensions, and are stated in advance. The following embodiments will further describe the related technical content of the present invention in detail, but the disclosed content is not intended to limit the protection scope of the present invention. In addition, the term "or" used in this document may include any one or a combination of more of the associated listed items depending on the actual situation.

Please refer to Figure 1, which is a system architecture diagram of a new type of electric curtain intelligent control system. As shown in Figure 1, the electric curtain intelligent control system provided by the present invention basically includes a control device 10, a monitoring device 11, a sensing device 12, a curtain device 13, a lighting device 14, and an air conditioning device 15.

In this embodiment, the monitoring device 11 may be or include a camera, and the camera may be a swing-head camera. In addition, the monitoring device 11 may also be a closed-circuit television (CCTV) monitoring device. In addition, the monitoring device 11 can capture indoor images.

In this embodiment, the sensing device 12 may be or include an outdoor illuminance sensor. In addition, the sensing device 12 can sense outdoor illuminance.

In this embodiment, the control device 10 may be a monitoring host, a control device, or a control box, which is not limited here. In addition, the control device 10 is coupled to the monitoring device 11, the sensing device 12, the curtain device 13, the lighting device 14, and the air conditioning device 15 respectively.

Furthermore, the control device 10 of this embodiment is configured to obtain different indoor illuminance values according to indoor images captured by the monitoring device 11 under different indoor illuminances, and compare them with the outdoor illuminance values sensed by the sensing device 12 to The curtain opening degree of the curtain device 13 is determined, the lighting brightness of the lighting device 14 is determined, and the air-conditioning setting of the air-conditioning device 15 is determined.

In detail, when the indoor illuminance is low, the indoor image captured by the monitoring device 11 is a low-illuminance image, and when the indoor illuminance is high, the indoor image captured by the monitoring device 11 is a high-illuminance image at this time, so The control device 10 can make indoor illuminance judgments based on indoor images taken by the monitoring device 11 under different indoor illuminances, so as to obtain different indoor illuminance values. In more detail, the control device 10 may determine the indoor illuminance based on the overall or partial characteristics (such as a certain point) of the captured indoor image.

In addition, the control device 10 compares the obtained indoor illuminance value with the outdoor illuminance value. When the outdoor illuminance value is low, the control device 10 can make the curtain opening of the curtain device 13 larger, and when the outdoor illuminance value is high, the control device 10 can make the curtain opening of the curtain device 13 smaller, so as to avoid over-exposure to the indoor device by sunlight. In addition, when the outdoor illuminance value is high, the control device 10 can turn on the air conditioning device 15 for temperature adjustment, and can reduce the brightness of the lighting device 14 to achieve energy saving.

In addition, the monitoring device 11 can also shoot indoor images of shadow changes produced when the room is irradiated by the sun from different locations in the room, so that the control device 10 can also obtain indoor images taken under different shades of sunlight generated by the monitoring device 11 in different directions of sunlight. Rizhao direction. In addition, the control device 10 can have GPS positioning function, and can also obtain the data of the solar longitude and latitude of the current area through a built-in database or obtain the data of the solar longitude and latitude of the current area through a networked method, so as to obtain the current location of the area. Sun position. In this way, the control device 10 can further determine the curtain opening of the curtain device 13, the brightness of the lighting device 14, and the air conditioning setting of the air conditioner 15 based on the assistance of the sunlight direction and the sun position. For example, the control device 10 may keep the blades of the curtain device 13 perpendicular to the direction of sunlight.

In an exemplary implementation aspect, with reference to FIG. 2, the monitoring device 11 may include a camera 111 coupled to the control device 10. The monitoring device 11 may be coupled to the control device 10 in a wireless manner or in a wired manner, and is not limited.

Furthermore, as shown in FIG. 2, the sensing device 12 may include an outdoor illuminance sensor 121, an outdoor temperature and humidity sensor 122, a wind speed and direction detector 123, a rainfall detector 124, and an indoor temperature sensor. A humidity sensor 125 and a device power detector 126 are respectively coupled to the control device 10. The sensing device 12 can be wirelessly or wiredly coupled to the control device 10, without limitation, and the specific implementation and quantity of various detectors in the sensing device 12 can be appropriately changed according to actual needs. .

In an exemplary implementation aspect, as shown in FIG. 3, the curtain device 13 may include a curtain body 131 and a curtain control device 132 coupled to the curtain body 131. Among them, the curtain body 131 may be, for example, a jalousie. In addition, the curtain control device 132 may include a main control device 1321, a power supply device 1322 that is respectively coupled to the main control device 1321, a driving device 1323, and a transmission device 1324.

In an exemplary implementation aspect, as shown in FIG. 4, the control device 10 may include an application interface 101, a central processing unit 104, a data storage unit 105, and a communication unit 106. The central processing unit 104 is respectively coupled to the application interface 101, the data storage unit 105, and the communication unit 106. Furthermore, the application interface 101 can be an interface generated by the integration of software and hardware, for example, can be constructed through a liquid crystal display screen, a touch screen, etc., and can be an interactive interface. In addition, the application interface 101 and the buttons may be physical or virtual interfaces, and the implementation modes are only examples, and are not intended to limit the scope of the present invention.

In this embodiment, the application interface 101 can include or be divided into a graphical analysis interface 102 and a man-machine interface 103. In an exemplary implementation aspect, with reference to FIG. 5, the graphical analysis interface 102 further includes a user setting module 1021, an analysis module 1022, and a storage and output module 1023. The user setting module 1021 is configured for the user to make settings, such as graphic selection, alarm setting, auxiliary environment scanning setting, distance correction setting, etc., but it is not limited to this, and can be appropriately changed according to actual needs. The analysis module 1022 is configured to perform graphic analysis, such as identifying the direction of sunlight according to indoor images taken by the monitoring device 11 in FIG. 1 under different shadows of sunlight, calculating the area illuminance according to the overall or partial characteristics of the indoor image, and calculating the overall or local image according to the indoor image. The local feature calculates the object distance or area distance, but it is not limited to this, and can be appropriately changed according to actual needs. The storage and output module 1023 is configured to store and output analysis results, such as storage of alarm images, analysis and calculation, and output of records, but is not limited to this, and can be changed appropriately according to actual needs. Each module in the above-mentioned graphic analysis interface 102 may be a software module executed by a central processing unit. In some embodiments, the module in the graphical analysis interface 102 may also be a hardware module of an integrated circuit (IC).

In an exemplary implementation aspect, with reference to FIG. 6, the man-machine interface 103 further includes a user interface setting module 1031, a control module 1032, and a recording and output module 1033. The user interface setting module 1031 is configured for the user to perform interface settings, such as page editing, communication settings, device settings, permission settings, and alarm settings, but it is not limited to this, and can be appropriately changed according to actual needs. The control module 1032 is configured to perform self-defined process control, automatic scheduling control, and automatic day tracking control, etc., but it is not limited to this, and can be appropriately changed according to actual needs. The recording and output module 1033 is configured to generate and output records, such as generating programming records, status records, communication records, trend records, and generating report output, but it is not limited to this, and can be appropriately changed according to actual needs. Each module in the above-mentioned human-machine interface 103 may be a software module executed by a central processing unit. In some embodiments, the module in the human-machine interface 103 may also be a hardware module of an integrated circuit.

Furthermore, with reference to FIG. 7, the control module 1032 includes a self-defined process control module 10321, and the self-defined process control module 10321 also includes a self-defined temperature control module 103211 and a self-defined energy-saving control module 103212. Among them, the self-defined temperature control module 103211 is configured to perform the steps of self-defined temperature control. Specifically, as shown in FIG. 8, it includes the following steps: obtaining sensing parameters, which can be performed by each of the sensing devices The sensor obtains the sensing parameter; then, calculates the average value of the obtained sensing parameter in a period of time. The average value of the sensing parameter in the period includes the average of outdoor temperature and humidity parameters and the average of indoor temperature and humidity. Then, compare the average value of the outdoor temperature and humidity parameters with the average value of the indoor temperature and humidity to obtain a comparison result; then, if the user has set the comfort parameters according to personal preferences, For example, if the temperature and humidity value or light intensity preferred by people with high body temperature or people with low body temperature, the comfort parameter is substituted; then, according to the comparison result and the comfort parameter, the air conditioning setting and curtain opening are determined; Finally, it can be set to cycle monitoring. Therefore, by the control device with self-defined temperature control function, temperature control according to personal preference and optimal temperature control can be achieved.

With reference to FIG. 7, the self-defined process control module 10321 may include a self-defined energy-saving control module 103212. Wherein, the self-defined energy-saving control module 103212 is configured to perform the steps of self-defined energy-saving control. Specifically, as shown in FIG. 9, it includes the following steps: obtaining sensing parameters, which can be performed by each of the sensing devices The sensor obtains the sensing parameter; then, calculates the average value of the obtained sensing parameter in a period of time. The average value of the sensing parameter in the period includes the average value of indoor temperature and humidity, the average value of indoor illuminance, And the average value of outdoor illuminance to avoid being affected by extreme values; then, compare the average value of the indoor temperature and humidity, the average value of the indoor illuminance, and the average value of the outdoor illuminance to obtain a comparison result; then, according to the Compare the results to determine the air conditioning settings, determine the brightness of the lighting, and determine the opening of the curtains; finally, it can be set to cycle monitoring. Therefore, the best energy-saving control can be achieved by the control device having a self-defined energy-saving control function.

In addition, as shown in FIG. 7, the control module 1032 also includes an automatic scheduling control module 10322. Among them, the automatic scheduling control module 10322 is configured to perform the steps of automatic scheduling control. Specifically, as shown in FIG. 10, it includes the following steps: get the current time; then, check the scheduled time; then, According to the schedule time, determine the curtain opening, determine the lighting brightness, and determine the air conditioning settings. For example, the schedule time is to determine the curtain opening, determine the lighting brightness, and determine the air conditioning at different times of the morning, noon, and evening of a certain day Set up. And, it can be set to cyclic monitoring. Therefore, with the automatic scheduling control function of the control equipment, the best scheduling control can be achieved.

Furthermore, with reference to FIG. 7, the control module 1032 also includes an automatic sun tracking control module 10323. Among them, the automatic sun tracking control module 10323 is configured to perform the steps of automatic sun tracking control. Specifically, as shown in FIG. 11, it includes the following steps: Obtain the direction of the sun, which can be performed by the monitoring device in the shadow of different suns The indoor image is taken to identify the direction of sunlight; then, the longitude and latitude of the sun are obtained, which can be obtained from a database or connected to the Internet as auxiliary information; then, the sensing parameters are obtained, which can be obtained by each of the sensing devices. The sensor obtains the sensing parameter; then, calculates the average value of the obtained sensing parameter in a period of time, and the average value of the sensing parameter in the period includes the average value of outdoor illuminance and the average value of indoor illuminance to Avoid being affected by extreme values; then, compare the average value of the outdoor illuminance with the average value of the indoor illuminance to obtain a comparison result; then, if the user has set comfort parameters according to personal preferences, such as those with a high body temperature Or the temperature and humidity value or light intensity preferred by people with low body temperature are substituted into the comfort parameter; then, according to the comparison result and the comfort parameter, the curtain opening degree, the lighting brightness, and the air conditioning setting are determined. And, it can be set to cyclic monitoring. Therefore, the control device has an automatic sun tracking control function, so that the curtain opening, lighting brightness, and air conditioning settings can be intelligently controlled according to the indoor and outdoor lighting conditions, and the best intelligent control can be achieved.

In addition, with reference to FIG. 12, it is a schematic diagram of an implementation aspect of the electric curtain intelligent control system of the new type. The figure shows a camera 111 installed indoors and an outdoor illuminance sensor installed on a window W. 121. The wind speed and direction detector 123 installed outdoors, the rainfall detector 124 installed outdoors, the indoor temperature and humidity sensor 125 installed indoors, the device power detector 126 installed indoors, the window W installed The curtain device 13 nearby, the lighting device 14 installed indoors, and the air-conditioning device 15 installed indoors. It should be noted that the intelligent control system of the electric curtain of the present invention is not limited to the implementation mode of FIG. 12, and can be appropriately changed according to actual design requirements.

Based on the above, the electric curtain intelligent control system provided by the embodiment of the present invention can shoot indoor illuminance images through the monitoring device 11, the sensing device 12 can sense outdoor illuminance, and the control device 10 can operate in 11 different rooms according to the monitoring device 11 Different indoor illuminance values obtained from indoor images taken under illuminance are compared with the outdoor illuminance values sensed by the sensing device 12 to determine the curtain opening of the curtain device 13, determine the brightness of the lighting device 14, and determine the air conditioner The air-conditioning setting of the device 15 can intelligently control the opening of the curtain, the brightness of the lighting, and the air-conditioning setting according to the indoor and outdoor lighting conditions, so as to achieve the best intelligent control and enhance the user experience.

The content disclosed above is only a preferred and feasible embodiment of the present model, and does not limit the scope of the patent application of the present model. Therefore, all equivalent technical changes made by using the description and schematic content of the present model are included in the application of the present model. Within the scope of the patent.

10: Control equipment 101: Application Interface 102: Graphical Analysis Interface 1021: User setting module 1022: Analysis Module 1023: Storage and output module 103: Human-Machine Interface 1031: User interface setting module 1032: control module 10321: Customized process control module 103211: Custom temperature control module 103212: Customized energy-saving control module 10322: Automatic scheduling control module 10323: Automatic sun tracking control module 1033: Record and output module 104: Central Processing Unit 105: data storage unit 106: communication unit 11: Monitoring equipment 111: Camera 12: Sensing equipment 121: Outdoor Illumination Sensor 122: outdoor temperature and humidity sensor 123: Wind speed and direction detector 124: Rainfall Detector 125: Indoor temperature and humidity sensor 126: Device Power Detector 13: curtain equipment 131: Curtain body 132: Curtain control device 1321: Master control device 1322: power supply device 1323: drive device 1324: transmission device 14: lighting equipment 15: Air conditioning equipment W: window

Figure 1 is a system architecture diagram of a new type of electric curtain intelligent control system.

Figure 2 is a structural diagram of a monitoring device and a sensing device according to an implementation aspect of the new type.

Fig. 3 is a structural diagram of a curtain device according to an embodiment of the new type.

Fig. 4 is a structural diagram of a control device according to an embodiment of the new type.

Fig. 5 is a structural diagram of a graphical analysis interface of an implementation aspect of the new type.

Fig. 6 is a structural diagram of a human-machine interface of an implementation aspect of the new type.

FIG. 7 is a structural diagram of a control module according to an embodiment of the new type.

Fig. 8 is a flowchart of a self-set temperature control according to an embodiment of the new type.

Fig. 9 is a flowchart of a self-defined energy-saving control in an embodiment of the new type.

Fig. 10 is a flowchart of automatic scheduling control according to an embodiment of the new type.

Fig. 11 is a flowchart of automatic sun tracking control according to an embodiment of the new type.

Fig. 12 is a schematic diagram of an implementation aspect of a new type of electric curtain intelligent control system.

10: Control equipment

11: Monitoring equipment

12: Sensing equipment

13: curtain equipment

14: lighting equipment

15: Air conditioning equipment

Claims (12)

An intelligent control system for electric curtains includes: control equipment, monitoring equipment, sensing equipment, curtain equipment, lighting equipment, and air conditioning equipment, and the control equipment is respectively coupled to the monitoring equipment, the sensing equipment, the curtain equipment, and the Lighting equipment, and the air-conditioning equipment; wherein the monitoring equipment can capture indoor images, the sensing equipment can sense outdoor illuminance, and the control equipment is configured to obtain indoor images captured by the monitoring equipment under different indoor illuminances Different indoor illuminance values are compared with the outdoor illuminance values sensed by the sensing device to determine the curtain opening of the curtain device, determine the lighting brightness of the lighting device, and determine the air conditioning settings of the air conditioning device. The intelligent control system for electric curtains according to claim 1, wherein the monitoring device is a camera coupled to the control device. The intelligent control system for electric curtains according to claim 1, wherein the sensing device includes an outdoor illuminance sensor coupled to the control device. The electric curtain intelligent control system according to claim 3, wherein the sensing device further includes an outdoor temperature and humidity sensor, a wind speed and direction detector, a rainfall detector, an indoor temperature and humidity sensor, and A device power detector is respectively coupled to the control device. The intelligent control system for electric curtains according to claim 1, wherein the control device is further configured to obtain the sunlight direction according to indoor images taken under different sunlight shadows generated by the monitoring device in different sunlight directions, and the control device is further configured to use To obtain the solar longitude and latitude of the current area to obtain the sun position, the control device further determines the curtain opening of the curtain device, determines the lighting brightness of the lighting device, and determines the air conditioner according to the sunlight direction and the sun position Air conditioning settings of the device. The electric curtain intelligent control system according to claim 1, wherein the control device includes an application interface, a central processing unit, a data storage unit, and a communication unit, and the central processing unit is respectively coupled to the application interface and the The data storage unit and the communication unit. The electric curtain intelligent control system according to claim 6, wherein the application interface contains a graphic analysis interface, and the graphic analysis interface further includes a user setting module, an analysis module, and a storage and output module. The user setting The module configuration is used for user settings, the analysis module is configured for graphical analysis, and the storage and output module is configured for storage and output of analysis results. The electric curtain intelligent control system according to claim 7, wherein the application interface further includes a man-machine interface, and the man-machine interface further includes a user interface setting module, a control module, and a recording and output module, the user The interface setting module is configured for users to configure the interface, the control module is configured to perform custom process control, automatic scheduling control, and automatic day tracking control, and the record and output module are configured to generate and output records . The electric curtain intelligent control system according to claim 8, wherein the control module includes a self-defined process control module, the self-defined process control module includes a self-defined temperature control module, and the self-defined temperature control module The step of configuring for performing self-defined temperature control includes: acquiring a sensing parameter; calculating the average value of the acquired sensing parameter in a period of time, and the average value of the sensing parameter in the period includes the outdoor temperature and humidity parameter The average value and the average value of the indoor temperature and humidity; compare the average value of the outdoor temperature and humidity parameters and the average value of the indoor temperature and humidity to obtain a comparison result; substitute the comfort parameter; determine according to the comparison result and the comfort parameter Air conditioning settings and determine the opening degree of curtains. The electric curtain intelligent control system according to claim 8, wherein the control module includes a self-defined process control module, the self-defined process control module includes a self-defined energy-saving control module, and the self-defined energy-saving control module The step of configuring to perform self-defined energy-saving control includes: acquiring a sensing parameter; calculating the average value of the acquired sensing parameter in a period of time, and the average value of the sensing parameter in the period includes the average of indoor temperature and humidity Value, the average value of outdoor temperature and humidity, the average value of indoor illuminance, and the average value of outdoor illuminance; compare the average value of indoor temperature and humidity, the average value of outdoor temperature and humidity, the average value of indoor illuminance, and the average value of outdoor illuminance The average value is used to obtain a comparison result; according to the comparison result, air conditioning settings, lighting brightness, and curtain opening are determined. The electric curtain intelligent control system according to claim 8, wherein the control module includes an automatic scheduling control module, and the automatic scheduling control module is configured to perform the steps of automatic scheduling control, including: obtaining the current time ; Check the schedule time; according to the schedule time, determine the curtain opening, determine the brightness of the lighting, and determine the air conditioning settings. The electric curtain intelligent control system according to claim 8, wherein the control module includes an automatic sun tracking control module, and the automatic sun tracking control module is configured to perform the steps of automatic sun tracking control, including: obtaining the direction of sunlight Obtain the longitude and latitude of the sun; Obtain the sensing parameter; Calculate the average value of the acquired sensing parameter in a period of time. The average value of the sensing parameter in the period includes the average value of outdoor illuminance and the average value of indoor illuminance; compare The average value of the outdoor illuminance and the average value of the indoor illuminance are compared to obtain a comparison result; the comfort parameter is substituted; according to the comparison result and the comfort parameter, the curtain opening degree, the lighting brightness, and the air conditioning setting are determined.

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