CN217558082U - Automatic skylight controller - Google Patents

Abstract

The application provides an automatic skylight controller, automatic skylight controller includes: detection component, control module and driver. The detection assembly comprises a first sensor group and a second sensor group, wherein the first sensor group is used for detecting environmental information data at the skylight, and the second sensor group is used for detecting state information data of the automatic skylight controller; the control module is connected with the detection assembly, receives and processes the environmental information data and the state information data, generates an action instruction and sends the action instruction to the driver; and the driver completes the state control of the skylight according to the action command. The automatic skylight controller can adaptively control the state of the skylight according to the change of the environment around the skylight.

Description

Automatic skylight controller

Technical Field

The application relates to the field of industrial production, in particular to an automatic skylight controller suitable for a skylight of a large building.

Background

In the construction of large buildings, skylights are generally installed on the roofs of the buildings in order to meet the requirements of ventilation, lighting, fire protection and the like of the buildings. When an emergency (e.g., a fire) occurs in a building and needs to be cleared, the control of the state of the skylight also has certain difficulty due to the particularity of the position of the skylight.

Common skylight control modes are mechanical control and voice control. The mechanical control mode needs additional mechanical control equipment, the internal structure of the mechanical control equipment is often more complicated, and manual operation is needed, which consumes manpower.

The voice control mode is generally to remotely control the state of the skylight through an artificial voice instruction, but in most buildings, such as industrial plants, shopping malls, stations, airports and other places, the problems of dense people flow, high noise and the like exist, and these problems can affect the operation accuracy of the voice control skylight, and can cause the phenomenon of misoperation.

Therefore, it is a technical problem to be solved to design an intelligent automatic skylight controller, which can adaptively complete the skylight state control when an emergency occurs in a building where the intelligent automatic skylight controller is located.

SUMMERY OF THE UTILITY MODEL

The application provides an automatic skylight controller, and the automatic skylight controller includes detection component and control module and driver, and the automatic skylight controller can be according to the state of outside environmental change self-adaptation's control skylight.

The application provides an automatic skylight controller includes: the detection assembly comprises a first sensor group and a second sensor group, wherein the first sensor group is used for detecting environmental information data at the skylight, and the second sensor group is used for detecting state information data of the automatic skylight controller; the control module is connected with the detection assembly, receives and processes the environmental information data and the state information data, and generates an action instruction; and the driver is connected with the control module, and the control module controls the driver to complete the state control of the skylight according to the action command.

According to some embodiments of the application, the first sensor group comprises: the rainfall detection sensor is connected with the control module and used for detecting rainfall data at the skylight; the humidity and temperature detection sensor is connected with the control module and is used for detecting humidity data and temperature data at the skylight; the light quantity detection sensor is connected with the control module and is used for detecting light quantity data at the skylight; and the air volume detection sensor is connected with the control module and is used for detecting air volume data at the skylight.

According to some embodiments of the application, the second sensor group comprises: the motor current detection sensor is connected with the control module and is used for detecting the driving current data of a driver of the automatic skylight controller; the power supply current detection sensor is connected with the control module and is used for detecting power supply current data of the control module of the automatic skylight controller; and the peripheral current detection sensor is connected with the control module and is used for detecting the current data of the peripheral equipment of the automatic skylight controller.

According to some embodiments of the application, the detection assembly further comprises: and the encoder is connected with the control module and the driver so as to detect the position information of the skylight.

According to some embodiments of the application, the automatic sunroof controller further comprises: the dual power supplies comprise a switching power supply and a lithium battery charging power supply.

According to some embodiments of the present application, the automatic sunroof controller further includes: and the display module is connected with the control module and displays the skylight state.

According to some embodiments of the present application, the automatic sunroof controller further includes: the storage module is connected with the control module and stores the environmental information data and the state information data on line.

According to some embodiments of the application, the automatic sunroof controller further comprises: the fire-fighting linkage module is connected with the control module and is connected with an external fire-fighting linkage system.

According to some embodiments of the application, the processor of the control module employs a microprocessor of a vehicle scale chip.

According to some embodiments of the present application, the sunroof controller further includes an output module connected to the control module and outputting the environmental information data to the outside.

The technical scheme that this application provided is through the state in automatic skylight controller control skylight to the realization is to the remote control in skylight.

When an emergency occurs in a building where a skylight is installed, such as a fire, a sudden rain, or a wind, the skylight needs to be opened or closed urgently. The application provides an automatic skylight controller can be through the change of the environmental information data perception external environment that detects, the state in self-adaptation according to the condition needs control skylight (for example in time open the skylight when conflagration, in time close the skylight when blowing out the wind and raining to and the angle of opening and shutting of control skylight with indoor wind pressure etc. of balancing).

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 shows a schematic structural diagram of a detection assembly according to an example embodiment;

fig. 2 shows a schematic structural view of an automatic sunroof controller according to an example embodiment.

The reference numbers illustrate:

an automatic sunroof controller 1; a detection assembly 10; a first sensor group 110; a rainfall amount detection sensor 111; a humidity-temperature detection sensor 113; a light amount detection sensor 115; an air volume detection sensor 117; a second sensor group 120; a motor current detection sensor 121; a supply current detection sensor 123; a peripheral current detection sensor 125; an incremental encoder 130; a control module 20; a driver 30; a dual power supply 40; a switching power supply 401; a lithium battery charging power supply 403; a display module 50; a storage module 60; a fire-fighting linkage module 70; and an output module 80.

Detailed Description

Example embodiments will now be described more fully with reference to the accompanying drawings. Example embodiments may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of example embodiments to those skilled in the art. The same reference numerals denote the same or similar parts in the drawings, and thus, a repetitive description thereof will be omitted.

The described features, structures, or characteristics may be combined in any suitable manner in one or more embodiments. In the following description, numerous specific details are provided to give a thorough understanding of embodiments of the disclosure. One skilled in the relevant art will recognize, however, that the embodiments of the disclosure can be practiced without one or more of the specific details, or with other means, components, materials, devices, or the like. In such cases, well-known structures, methods, devices, implementations, materials, or operations are not shown or described in detail.

Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

The terms "first," "second," and the like in the description and claims of the present application and in the foregoing drawings are used for distinguishing between different objects and not for describing a particular sequential order. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions.

The application provides an automatic skylight controller 1 for controlling the state of a skylight in a self-adaptive manner according to the environment where the skylight is located. The present application will be described in detail below with reference to fig. 1-2.

According to an exemplary embodiment, fig. 1 shows a schematic configuration of a detection assembly according to an exemplary embodiment, and fig. 2 shows a schematic configuration of an automatic sunroof controller according to an exemplary embodiment.

Referring to fig. 1 and 2, the sunroof controller 1 includes a detection assembly 10, a control module 20, and a driver 30. The sensing assembly 10 includes a first sensor group 110 and a second sensor 120.

The first sensor group 110 includes a rainfall detection sensor 111, and the rainfall detection sensor 111 is disposed outside the roof skylight and collects rainfall data outside the skylight.

When the building where the skylight is located rains, the rainfall detection sensor 111 can automatically detect information such as the amount of rainfall and the rainfall intensity at the skylight.

The automatic skylight controller 1 senses whether the skylight, i.e., the building is rained or not according to the rainfall information collected by the rainfall detection sensor 111, and adaptively determines whether the skylight needs to be automatically closed or not.

The first sensor group 110 further comprises a humidity and temperature detection sensor 113, wherein the humidity and temperature detection sensor 113 is arranged inside a skylight of a roof, and collects indoor temperature and humidity data inside the skylight.

The first sensor group 110 further includes a light quantity detection sensor 115, and the light quantity detection sensor 115 is disposed outside the roof skylight and collects light quantity information outside the skylight, such as whether the skylight is located with light or not, light intensity, and other data.

The automatic sunroof controller 1 determines whether there is light at the position of the sunroof based on the light amount detection sensor 115, and determines the current time zone (day or night) of the building in which the sunroof is located.

The first sensor group 110 further includes an air volume detection sensor 117, and the air volume detection sensor 117 is disposed outside the skylight of the roof, and collects air volume information outside the skylight, for example, whether the skylight is located with wind, wind speed, wind direction, and other data.

Automatic sunroof controller 1 determines whether wind is present at the sunroof based on wind volume detection sensor 117, determines external environment information of the building in which the sunroof is present, and obtains the wind speed and wind direction of the external environment based on data detected by wind volume detection sensor 117.

The automatic skylight controller 1 adjusts the opening and closing of the skylight or the opening and closing angle of the skylight in a self-adaptive manner according to the wind speed and the wind direction of the external environment so as to control the wind pressure inside the building, so that the wind pressure inside the building is balanced to a certain degree.

According to an example embodiment, the first sensor group 110 includes a rainfall detection sensor 111, a temperature and humidity detection sensor 113, a light amount detection sensor 115, and a wind amount detection sensor 117. The first sensor group 110 collects environmental information data of the skylight through a plurality of detection sensors distributed at different positions, including rainfall data, temperature and humidity data, light quantity data and air quantity data of the skylight.

According to an exemplary embodiment, referring to fig. 2, the first sensor group 110 is connected to the control module 20, and transmits the environmental information data of the skylight collected by the first sensor group 110 to the control module 20 through the CAN wired network.

The automatic skylight controller 1 senses the environmental state of the skylight by acquiring the environmental information data of the skylight, and self-judges the state of the skylight (such as opening the skylight, closing the skylight, and the opening and closing angle of the skylight) according to the environmental information data.

According to an exemplary embodiment, referring to fig. 1, the detection assembly 10 further comprises a second sensor group 120, the second sensor group 120 detecting system status information data of the sunroof controller 1. Referring to fig. 1, the second sensor group 120 includes a motor current detection sensor 121, and the motor current detection sensor 121 is disposed at the driver 30 and collects a driving current of the dc motor driver 30 of the sunroof. When the driver 30 is in operation, the drive current will increase significantly.

The second sensor group 120 further includes a supply current detection sensor 123, and the supply current detection sensor 123 is disposed at the control module 20 and collects a supply current of the control system at the control module 20.

When the driver 30 is in an operating state, the driving current of the dc motor driver 30 may be significantly increased. The abnormal conditions of opening and closing of the skylight are monitored by detecting the driving current data and the power supply current data so as to facilitate the automatic skylight controller 1 to carry out system self-check, and if the driving current data and/or the power supply current data are detected to be overlarge, the abnormal conditions are considered to occur, and an alarm is required.

The second sensor group 120 further includes a peripheral current detection sensor 125, and the peripheral current detection sensor 125 is disposed at the control module 20 and collects currents of other electrical components of the sunroof controller 1 except the control module 20 and the driver 30. The power consumption condition of the external device at the control module 20 is detected by detecting the current of other electrical components, and the device state is self-checked through the power consumption condition.

According to an example embodiment, the second sensor group 120 includes a motor current detection sensor 121, a supply current detection sensor 123, and a peripheral current detection sensor 125. The second sensor group 120 collects internal state information data of the automatic skylight controller 1 through a plurality of detection sensors, and performs state self-detection on internal systems of the automatic skylight controller 1 according to current conditions of various internal devices, so as to ensure normal operation of the devices.

According to an exemplary embodiment, referring to fig. 1, the detection assembly 10 comprises a plurality of detection sensors to detect environmental information data of the sunroof in which the sunroof is located and status information data of the automatic sunroof controller 1.

The environmental information data and the state information data form multi-sensor perception fusion data, advantages of various sensors can be balanced through multi-sensor data fusion, a single component is utilized to obtain larger computing capacity, metering of a computing result is improved, and known data redundancy among sensor data is eliminated.

The multi-sensor data fusion carries out multi-level and multi-aspect information complementation and optimized combination processing on various sensors, and finally achieves all-aspect detection on the observation environment, and the intelligence of the multi-sensor system is improved through data multi-aspect integration.

Optionally, referring to fig. 1, the detecting assembly 10 further includes an incremental encoder 130, the incremental encoder 130 is disposed at the dc motor driver 30, and the incremental encoder 130 can convert the displacement into a periodic electrical signal. The incremental encoder 30 is connected to the control module 20 and detects the position information of the skylight.

The incremental encoder 130 converts the position information of the driver 30 into an electric signal to be output by calculating the number of rotations of the motor of the driver 30 and the transmission gear ratio, so as to detect the position information of the skylight in real time.

Fig. 2 shows a schematic structural diagram of an automatic sunroof controller according to an example embodiment, and referring to fig. 2, an automatic sunroof controller 1 includes a detection assembly 10, a control module 20, and a driver 30.

Referring to fig. 2, the control module 20 is connected to the detection assembly 10 through the CAN wired network, and receives environmental information data of the skylight detected by the detection assembly 10 and status information data of the automatic skylight controller 1.

The control module 20 receives the context information data and the status information data and automatically generates action instructions.

According to an example embodiment, the environmental information data and the state information data constitute multi-sensor-aware fusion data from which the control module 20 generates action instructions.

The control module 20 can balance the advantages of various sensors through multi-sensor data fusion, and integrate and utilize local resources collected by different types of detection sensors distributed at different positions to obtain a comprehensive decision result.

According to an exemplary embodiment, when the building where the skylight is located needs emergency windowing and ventilation when a fire breaks out, the detection assembly 10 collects indoor temperature and humidity data inside the skylight and outdoor light quantity data and air quantity data outside the skylight and forms multi-sensor sensing fusion data.

The control module 20 receives the multi-sensor sensing fusion data and identifies a fire condition based on the multi-sensor sensing fusion data. The control module 20 obtains an action instruction for opening the skylight and the opening and closing angle of the skylight by combining the time (day or night) when a fire occurs and the outdoor air volume (wind speed and wind direction) according to the outdoor light quantity data and the outdoor air volume data outside the skylight. The driver 30 receives the operation command to complete the state control of the sunroof.

According to an exemplary embodiment, when the environment outside the building where the skylight is located needs to be closed urgently for rain, the detection assembly 10 collects indoor temperature and humidity data of the skylight and outdoor light quantity data, rainfall data and air quantity data outside the skylight, and forms multi-sensor sensing fusion data.

The control module 20 receives the multi-sensor sensing fusion data and recognizes rain based on the multi-sensor fusion data. The control module 20 obtains an action instruction for closing the skylight or the opening and closing angle of the skylight according to the outdoor light quantity data, the rainfall data and the air quantity data outside the skylight and by combining the time (day or night) when rain occurs, the rainfall and the outdoor air quantity (wind speed and wind direction). The driver 30 receives the operation command to complete the state control of the sunroof.

According to an exemplary embodiment, when the building where the skylight is located is in a normal environment, the detection assembly 10 collects indoor temperature and humidity data inside the skylight and outdoor light quantity data and air quantity data outside the skylight and forms multi-sensor sensing fusion data.

The control module 20 receives the multi-sensor sensing fusion data, and obtains action instructions such as skylight closing or skylight opening and closing angle and the like according to indoor temperature and humidity data inside the skylight and outdoor light quantity data and air quantity data outside the skylight and combining the humidity and the temperature inside the skylight and the air quantity (wind speed and wind direction) of the external environment, so that indoor air pressure of the building is controlled to be in a balanced state, and the requirements of ventilation and pressure relief of the skylight in the building are met.

The control module 20 utilizes individual components to obtain greater computational power, improves the metering of computational results, and, in conjunction with self-learning analysis of historical data, eliminates known data redundancy between individual sensor data.

The control module 20 obtains environmental information data of the position of the skylight and self-running state information data of the automatic skylight controller 1 through multi-sensor data fusion, senses external environmental changes, and adaptively controls the states (opening, closing, opening and closing angles and the like) of the skylight according to the environmental changes and the self-running state.

Referring to fig. 2, the driver 30 is connected to the control module 20, and the driver 30 receives the action command generated by the control module 20 and completes the opening or closing of the sunroof according to the action command.

Optionally, referring to fig. 2, the sunroof controller provided herein further includes a dual power supply 40.

The dual power supply 40 includes a switching power supply 401 and a lithium battery charging power supply 402. The switching power supply is 220v power connection power supply, and the switching power supply 401 is connected with the automatic skylight controller 1 and provides external power support for the automatic skylight controller 1.

The lithium battery charging power supply 402 is connected with the switching power supply 401, and when the sunroof controller 1 is in a normal operation state, the switching power supply 401 maintains a charging mode for the lithium battery charging power supply 402.

When an emergency (for example, a fire) occurs in the building where the automatic skylight controller 1 is located, the switching power supply 401 is powered off under the influence of the outside, and at the moment, the lithium battery charging power supply 402 starts to work to provide electric support for the automatic skylight controller 1, so that the skylight can be normally controlled during fire fighting, and the skylight can normally implement a ventilation and smoke exhaust function.

The dual power supply 40 provides dual power supply guarantee for the sunroof controller 1 through the switching power supply 401 and the lithium battery charging power supply 402, and the independent lithium battery charging power supply 402 serves as a 24-hour online backup power supply.

When the fire-fighting problem of the building causes the switching power supply 401 to be cut off, the lithium battery charging power supply 402 provides power for the automatic skylight controller 1, so that the automatic skylight controller 1 can normally control the skylight state, the skylight can discharge smoke in time, and meanwhile, uploading of state information data during fire-fighting is also guaranteed.

According to an exemplary embodiment, the battery capacity of lithium battery charging source 402 provides more than thirty times for sunroof opening and closing operations and ensures that automatic sunroof controller 1 continues to operate for at least one hour.

The dual power supply 40 adopts a dual-system independent power supply mode, the power supplies of the control module 20 and the driver 30 are independently separated, and an isolation measure is adopted between the control module 20 and the driver 30, so that mutual interference between the power supplies is reduced.

Optionally, referring to fig. 2, the automatic sunroof controller 1 further includes a display module 50, and the display module 50 may display the current state of the sunroof (open, closed, opening, closing, opening and closing angle, etc.) in the form of a touch screen to implement human-computer information interaction.

The display module 50 may also display the current time to provide time information for the sunroof controller 1, so that the sunroof controller 1 can implement synchronous fusion of information data input by multiple sensors.

Optionally, referring to fig. 2, the automatic sunroof controller 1 further includes a storage module 60, the storage module 60 is connected to the control module 20, and the storage module 60 stores the multi-sensor sensing fusion data and saves the power loss on line.

When the automatic skylight controller 1 breaks down or is powered off accidentally, the historical storage data is retrieved and the normal working state is recovered through the storage module 60 after the automatic skylight controller is repaired.

Optionally, referring to fig. 2, the sunroof controller 1 further includes a fire-fighting linkage module 70, the fire-fighting linkage module 70 is connected to the control module 20, and the fire-fighting linkage module 70 is connected to an external fire-fighting linkage system.

The fire-fighting linkage system is an important component of an automatic fire alarm system. The fire-fighting linkage module 70 is connected to an external fire-fighting linkage system to complete communication and fire-fighting control between the sunroof controller 1 and the external fire-fighting linkage system.

Optionally, according to an example embodiment, the processor of the control module 20 employs a vehicle scale level microprocessor.

The vehicle-scale control unit CAN process CAN bus information and control logic to ensure the reliable operation of the system. The requirements of the vehicle-scale electronic components on the working temperature are wide, and different requirements are met according to different installation positions and the like.

The circuit design of the vehicle-scale processor can ensure that the control module 20 can keep normal operation of the control module 20 within a certain time in the process of a fire, so that the automatic skylight controller 1 can maintain the functions of skylight control, communication of the fire-fighting linkage module 70, field data transmission and the like within a certain time.

In the course of a fire, the smoke evacuation system of a building is of utmost importance. According to an example embodiment, the control module 20 can continue to normally work for about 10min under an environment of about 120 degrees by using the vehicle-scale-level microprocessor, so that the skylight can be normally controlled to be opened in the period, a good smoke exhaust effect is achieved, and the timely smoke exhaust has an important effect on fire protection of a large building.

Optionally, referring to fig. 2, according to an exemplary embodiment, the sunroof controller 1 further includes an output module 80, the output module 80 being connected to the control module 20.

When a building includes a plurality of skylights, one of the skylights includes the automatic skylight controller 1 described above, the output module 80 in the automatic skylight controller 1 outputs the environmental information data to the other skylights, and the other skylights receive the environmental information data and correspondingly control the states of the other skylights according to the environmental information data.

The output module 80 can realize information sharing of the environmental information data and other devices, save the cost of installing a plurality of detection sensors by other skylight control systems, and simultaneously achieve the purpose of synchronously controlling the states of a plurality of skylights of the building.

The technical scheme that this application provided is through the state in automatic skylight controller control skylight to the realization is to the remote control in skylight.

The technical scheme that this application provided has solved at present in large building (for example industrial factory building, shopping mall, airport, station etc.) because the particularity of skylight position, the difficult state scheduling problem in control skylight.

When an emergency occurs in a building where a skylight is located, such as a fire, sudden rain, or wind, the skylight needs to be opened or closed urgently. The application provides an automatic skylight controller can be through the change of the environmental information data perception external environment that detects, the state in self-adaptation according to the condition needs control skylight (for example in time open the skylight when conflagration, in time close the skylight when blowing out the wind and raining to and the angle of opening and shutting of control skylight with indoor wind pressure etc. of balancing).

This application detects skylight external environment data's change and automatic skylight controller self running state information data through detecting component 10, forms the multisensor perception with the data that detect and fuses the data, fuses the advantage that can balance various sensors through multisensor data, detects data multidirectional more, and is more comprehensive, has more accurate sensitivity.

Control module 20 carries out multi-level, many-sided information with the detection data of multiple sensor according to the multiple sensor data fusion and carries out complementation and optimal combination processing, finally reaches the detection of the whole aspect of observing the environment, has improved the intellectuality of multiple sensor system through many-sided integration of data, has improved the detection precision of environmental change.

The control module 20 generates an action instruction according to the multi-sensor sensing fusion data, and sends the action instruction to the driver 30, and the driver 30 completes the state control of the skylight according to the action instruction, so as to realize accurate automatic remote control of the skylight under different environmental conditions.

Finally, it should be noted that the above-mentioned embodiments are only preferred embodiments of the present application, and are not intended to limit the present application, and although the present application is described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the above-mentioned embodiments, or equivalents may be substituted for some of the technical features. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. An automatic sunroof controller, comprising:

the detection assembly comprises a first sensor group and a second sensor group, wherein the first sensor group is used for detecting environmental information data at the skylight, and the second sensor group is used for detecting state information data of the automatic skylight controller;

the control module is connected with the detection assembly, receives and processes the environmental information data and the state information data, and generates an action instruction;

and the driver is connected with the control module, and the control module controls the driver to complete the state control of the skylight according to the action command.

2. The automatic sunroof controller according to claim 1, wherein the first sensor set comprises:

the rainfall detection sensor is connected with the control module and is used for detecting rainfall data at the skylight;

the humidity and temperature detection sensor is connected with the control module and is used for detecting humidity data and temperature data at the skylight;

the light quantity detection sensor is connected with the control module and is used for detecting light quantity data at the skylight;

and the air volume detection sensor is connected with the control module and is used for detecting the air volume data at the skylight.

3. The automatic sunroof controller according to claim 1, wherein the second sensor group comprises:

the motor current detection sensor is connected with the control module and is used for detecting the driving current data of the driver of the automatic skylight controller;

the power supply current detection sensor is connected with the control module and is used for detecting power supply current data of the control module of the automatic skylight controller;

and the peripheral current detection sensor is connected with the control module and is used for detecting the current data of the peripheral equipment of the automatic skylight controller.

4. The automatic sunroof controller according to claim 1, wherein the detection assembly further comprises:

the encoder is connected with the control module and the driver to detect the position information of the skylight.

5. The automatic sunroof controller according to claim 1, further comprising:

the dual power supply comprises a switching power supply and a lithium battery charging power supply.

6. The automatic sunroof controller according to claim 1, further comprising:

and the display module is connected with the control module and displays the skylight state.

7. The automatic sunroof controller according to claim 1, further comprising:

and the storage module is connected with the control module and stores the environmental information data and the state information data on line.

8. The automatic sunroof controller according to claim 1, further comprising:

the fire-fighting linkage module is connected with the control module and is connected with an external fire-fighting linkage system.

9. The automatic sunroof controller according to claim 1, wherein the processor of the control module is a microprocessor of a vehicle-scale chip.

10. The automatic sunroof controller according to claim 1, further comprising:

and the output module is connected with the control module and outputs the environment information data to the outside.

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