A seat system

By prioritizing power supply to the environmental monitoring and emergency call modules and allocating power according to usage signals and weather conditions, the problem of unreasonable power supply for smart seats is solved, achieving efficient energy utilization and multi-functional support for the seat system.

CN122151677APending Publication Date: 2026-06-05ENTROPY CLOUD BRAIN MACHINE (HANGZHOU) TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
ENTROPY CLOUD BRAIN MACHINE (HANGZHOU) TECHNOLOGY CO LTD
Filing Date
2026-03-12
Publication Date
2026-06-05

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  • Figure CN122151677A_ABST
    Figure CN122151677A_ABST
Patent Text Reader

Abstract

The application discloses a seat system applied to the field of new energy technology, which continuously supplies power to an environment monitoring module and an emergency call module through a power supply module, supplies power to a mobile device charging module when a seat sitting signal is received, supplies power to a seat temperature control module when an extreme weather signal monitored by the environment monitoring module is received, supplies power to an illumination module when a night signal monitored by the environment monitoring module is received, and stops supplying power to the seat temperature control module and the mobile device charging module when the storage capacity of the seat system is less than a storage threshold. It can be seen that the environment monitoring module and the emergency call module are supplied with power in priority according to the power supply priority, the core functions are guaranteed to be realized, the charging module is supplied with power only when the user has a charging demand when using the seat, and the corresponding modules are supplied with power when there is a temperature control and illumination demand, so that the power supply is reasonably distributed, and the multifunctional demand of the user when using the seat is efficiently met.
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Description

Technical Field

[0001] This application relates to the field of new energy technology, and more specifically, to a seating system. Background Technology

[0002] In the process of building smart cities, outdoor public seating, as a basic public service facility, is facing increasingly diverse functional requirements. Traditional public seating only offers basic sitting and lying functions, and citizens only experience the basic functionality of the seating without any further comfort features. Today, smart seating integrates more convenient service modules.

[0003] However, the power distribution among the multi-functional modules of the smart seat is unreasonable, resulting in a waste of resources. Many modules are often in standby mode when there is no need for power, which can lead to insufficient power supply for core functions when energy is limited, and even the help function in emergency situations may fail due to power depletion.

[0004] Therefore, how to design a seating system to achieve intelligent power allocation for the multi-functional use of the seat and efficiently meet the multi-functional needs of users when using the seat is an issue that needs attention. Summary of the Invention

[0005] In view of the above problems, this application provides a seat system to realize intelligent power distribution for the multi-functional use of the seat, and efficiently meet the multi-functional needs of users when using the seat.

[0006] To achieve the above objectives, the following specific solutions are proposed: A seating system includes a seat, a power supply module, a mobile device charging module, an environmental monitoring module, an emergency call module, a lighting module, and a seat temperature control module. The power supply module is used for: Continuously supply power to the environmental monitoring module and the emergency call module; When a signal indicating that the seat has been occupied is received, power is supplied to the charging module of the mobile device; When the environmental monitoring module receives an extreme weather signal, it supplies power to the seat temperature control module. When the environment monitoring module detects a darkness signal, it supplies power to the lighting module. When the energy storage capacity of the seat system is less than the energy storage threshold, power supply to the seat temperature control module and the mobile device charging module is stopped.

[0007] Optionally, the mobile device charging module is used for: When a device to be charged is detected, the device type of the device to be charged is identified, and the charging protocol that matches the device type is determined. The device to be charged is charged according to the charging protocol, and the charging ends after a preset charging period.

[0008] Optionally, the mobile device charging module includes a wireless charging module disposed on both sides of the armrests of the seat, and a USB charging module embedded in the back of the seat.

[0009] Optionally, the seating system also includes a sensor set and a display screen, the sensor set including a temperature sensor, an ultraviolet sensor and an air quality sensor; The environmental monitoring module is used for: When the temperature detected by the temperature sensor is greater than the high temperature threshold, the display screen is controlled to show a high temperature warning message; When the ultraviolet intensity detected by the ultraviolet sensor is greater than the strong ultraviolet threshold, the display screen is controlled to show a strong ultraviolet warning message. When the PM2.5 value detected by the air quality sensor is greater than the first particle threshold, the display screen is controlled to show air quality alert information. When the temperature detected by the temperature sensor is within the comfortable temperature range, and the PM2.5 value detected by the air quality sensor is less than the second particle threshold, the display screen is controlled to display a comfort prompt message.

[0010] Optionally, the seat temperature control module includes a first semiconductor chip disposed on the seat surface and a second semiconductor chip disposed on the seat back, and the seat temperature control module is used for: When the seat temperature control module is powered on, it monitors the surface temperature of the seat based on the temperature sensor, and then powers the first and second semiconductor chips through the semiconductor Peltier effect to regulate the temperature.

[0011] Optionally, the sensor set further includes a pressure sensor disposed under the seat surface, and the seat temperature control module is further used for: When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and when the temperature sensor detects that the ambient temperature is greater than the ambient high temperature threshold, the cooling mode is activated to reduce the seat surface temperature of the seat to below the seat surface cooling temperature threshold. When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and the temperature sensor detects that the ambient temperature is less than the ambient low temperature threshold, the heating mode is activated to reduce the seat surface temperature to above the seat surface heating temperature threshold. When the temperature sensor detects that the ambient temperature is greater than the ambient extreme high temperature threshold or less than the ambient extreme low temperature threshold, it adjusts to the ready working state, wherein the ambient extreme high temperature threshold is greater than the ambient high temperature threshold, and the ambient extreme low temperature threshold is less than the ambient low temperature threshold.

[0012] Optionally, the power supply module is also used for: When the seat surface temperature is greater than the overheating temperature threshold or less than the overcooling temperature threshold, power supply to the seat temperature control module is stopped.

[0013] Optionally, the sensor set further includes an infrared sensor disposed above the seat, and the power supply module is further used for: When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and the infrared radiation signal detected by the infrared sensor is the thermal radiation signal of the target user, the system is adjusted to normal power supply mode. During normal power supply of the power supply module, if the pressure value detected by the pressure sensor is not greater than the preset pressure threshold, or if the infrared radiation signal is a non-thermal radiation signal, the power supply mode is adjusted to low power consumption mode. After the power supply module has been in the low-power power supply mode for a preset waiting time, the power supply is stopped, and the seat temperature control module is controlled to stop working.

[0014] Optionally, the emergency call module includes a seat flashing light, a buzzer, a voice broadcast unit, and an emergency button located on the inside of the armrest of the seat. The emergency call module is used for: In response to the operation of pressing the emergency button for a preset time, an emergency call action is executed, wherein the emergency call action includes controlling the seat flashing light to flash, controlling the buzzer to sound an alarm, controlling the voice broadcast unit to play an alarm voice, controlling the display screen to display emergency call information, and reporting the emergency information to the superior system.

[0015] Optionally, the seating system also includes a health monitoring module, and the sensor set further includes a heart rate sensor and a blood pressure sensor disposed on the armrests of the seat. The health monitoring module is used for: When the heart rate sensor detects an abnormal heart rate in the target user, it controls the voice broadcast unit to play a heart rate abnormality prompt voice and controls the display screen to display heart rate abnormality help interaction information. If no feedback information of the heart rate abnormality help interaction information is received after a preset interaction waiting time, it drives the emergency call module to execute the emergency call action. When the blood pressure sensor detects an abnormal blood pressure in the target user, it controls the voice broadcast unit to play a blood pressure abnormality prompt voice and controls the display screen to display blood pressure abnormality help interaction information. If no feedback information of the blood pressure abnormality help interaction information is received after a preset interaction waiting time, it drives the emergency call module to execute the emergency call action.

[0016] Using the above technical solution, the seat system of this application includes a seat, a power supply module, a mobile device charging module, an environmental monitoring module, an emergency call module, a lighting module, and a seat temperature control module. The power supply module continuously supplies power to the environmental monitoring module and the emergency call module. When it receives a seat-sitting signal, it supplies power to the mobile device charging module. When it receives an extreme weather signal detected by the environmental monitoring module, it supplies power to the seat temperature control module. When it receives a darkness signal detected by the environmental monitoring module, it supplies power to the lighting module. When the seat system's stored power is less than the stored power threshold, it stops supplying power to the seat temperature control module and the mobile device charging module. Therefore, power is prioritized for the environmental monitoring module and the emergency call module to ensure the core functions are implemented. Power is supplied to the charging module only when the user needs to charge the seat, and to the corresponding modules only when there are temperature control and lighting needs, thus rationally allocating power and efficiently meeting the user's multi-functional needs when using the seat. Attached Figure Description

[0017] Various other advantages and benefits will become apparent to those skilled in the art upon reading the following detailed description of preferred embodiments. The accompanying drawings are for illustrative purposes only and are not intended to limit the scope of this application. Furthermore, the same reference numerals denote the same parts throughout the drawings. In the drawings: Figure 1 A system structure diagram of a seating system provided in an embodiment of this application; Figure 2 A schematic diagram illustrating the power distribution process of the seating system provided in this application embodiment; Figure 3 This is a schematic diagram of the structural connection of a sensor set for a seat system provided in an embodiment of this application. Detailed Implementation

[0018] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.

[0019] Figure 1An optional system structure for a seating system provided in this application embodiment, such as... Figure 1 As shown, the seating system may include: a seat, a sensor set, a display screen, a power supply module, a mobile device charging module, an environmental monitoring module, an emergency call module, a lighting module, and a seat temperature control module.

[0020] The power supply module includes solar panels, an energy storage system, and a processing center. The solar panels, which can be located on the seat canopy for shading and power generation, can be 200W monocrystalline silicon solar panels with an area of ​​1.5m². 2 The conversion efficiency is ≥20%. The energy storage system uses lithium iron phosphate batteries with a capacity of 500Wh, which can provide 3-5 days of continuous operation on cloudy or rainy days.

[0021] Specifically, the power supply modules are connected to the seat, sensor array, display screen, mobile device charging module, environmental monitoring module, emergency call module, lighting module, and seat temperature control module. The power supply modules consistently provide power to the seat, sensor array, and display screen to enable their respective basic functions. When supplying power to each functional module, the power supply power can vary or be allocated as needed; for example, the mobile device charging module may be allocated 90W, the environmental monitoring module 5W, the seat temperature control module 50W, the lighting module 20W, and the emergency call module 5W.

[0022] based on Figure 1 The system architecture shown is as follows: Figure 2 This paper illustrates a flowchart of a power distribution process for a seat system provided in an embodiment of this application. (Refer to...) Figure 2 The process may include: Step S110: Continuously supply power to the environmental monitoring module and the emergency call module.

[0023] It is understandable that environmental monitoring and emergency call are basic service functions and life safety functions provided to citizens, respectively. Therefore, the environmental monitoring module and the emergency call module have power supply priority. Under normal circumstances, the power supply module can always supply power to the environmental monitoring module and the emergency call module to ensure that citizens can obtain environmental monitoring information from the seat system at any time and enjoy emergency rescue functions at any time.

[0024] Step S120: When a seat is received as a seated signal, power is supplied to the mobile device charging module.

[0025] Specifically, the seat can be equipped with a pressure sensor. When a user sits on the seat, if the pressure value of the pressure sensor exceeds the pressure threshold, it can trigger the generation of a sitting signal and transmit it to the power supply module. At this time, the power supply module can supply power to the mobile device charging module based on this received sitting signal, thereby providing charging service to the user of the seat.

[0026] It is understandable that power is supplied to the mobile device charging module only when a user is sitting on the seat. If no user is detected using the seat, no power is supplied to the mobile device charging module, so that the device cannot be charged through the charging port of the mobile device charging module, thereby avoiding waste of power resources.

[0027] Step S130: When an extreme weather signal is received from the environmental monitoring module, power is supplied to the seat temperature control module.

[0028] Specifically, extreme weather signals can indicate overheating or overcooling. When an extreme weather signal is encountered, the temperature sensor in the sensor array can capture the overheating / overcooling temperature values ​​on the seat surface. The environmental monitoring module identifies this situation as extreme weather, thus triggering the generation of an extreme weather signal. Understandably, if a user still uses the seat system in extreme weather conditions, the temperature needs to be adjusted for the user's comfort. Therefore, power can be supplied to the seat temperature control module to enable it to automatically adjust the seat temperature for comfort.

[0029] Step S140: When the night signal detected by the environmental monitoring module is received, power is supplied to the lighting module.

[0030] Understandably, current urban lighting strategies typically employ fixed-time lighting, such as turning on streetlights from 7 PM to 6 AM the following morning. This strategy fails to consider lighting needs under special weather conditions (such as dark, overcast skies). However, seating systems are equipped with lighting modules to provide illumination for citizens, thus offering lighting functionality even in dark environments.

[0031] Specifically, the light intensity sensor in the sensor set can sense the ambient light intensity in real time and transmit it to the environmental monitoring module. If the ambient light intensity is weak for a period of time, a darkness signal is generated and fed back to the power supply module. After receiving the darkness signal, the power supply module can supply power to the lighting module.

[0032] Step S150: When the energy storage capacity of the seat system is less than the energy storage threshold, stop supplying power to the seat temperature control module and the mobile device charging module.

[0033] Understandably, when the seat system has insufficient power (below 20%), it can stop non-core temperature control and charging functions to avoid excessive power consumption, ensure that critical services such as emergency calls and environmental data monitoring are not interrupted in extreme situations, and guarantee the normal use of high-priority functions.

[0034] The seating system provided in this embodiment includes a seat, a power supply module, a mobile device charging module, an environmental monitoring module, an emergency call module, a lighting module, and a seat temperature control module. The power supply module continuously supplies power to the environmental monitoring module and the emergency call module. When it receives a seat-sitting signal, it supplies power to the mobile device charging module. When it receives an extreme weather signal detected by the environmental monitoring module, it supplies power to the seat temperature control module. When it receives a darkness signal detected by the environmental monitoring module, it supplies power to the lighting module. When the seat system's stored power is less than the stored power threshold, it stops supplying power to the seat temperature control module and the mobile device charging module. Therefore, power is prioritized for the environmental monitoring module and the emergency call module to ensure core functions are implemented. Power is supplied to the charging module only when the user needs to charge the seat, and to the corresponding modules only when there are temperature control and lighting needs, thus rationally allocating power and efficiently meeting the user's multi-functional needs when using the seat.

[0035] In some embodiments of this application, the mobile device charging module mentioned in the above embodiments is described. The mobile device charging module includes a wireless charging module disposed on both sides of the armrests of the seat, and a USB charging module embedded in the back of the seat.

[0036] Specifically, the charging area of ​​the wireless charging module can be marked with an icon and an LED indicator. When the user places their phone in the marked area, the wireless charging module senses and charges. The LED light illuminates green during charging and turns off when the phone is fully charged or removed. The USB charging module can have four charging ports, each capable of 15W fast charging. Two USB-A ports can be provided for traditional devices, while two USB-C ports can be provided for newer devices or laptops. Each port outputs 5V / 3A (15W).

[0037] Furthermore, mobile device charging modules can be used for: When a device is detected to be plugged in, the device type of the device to be charged is identified, and the charging protocol that matches the device type is determined.

[0038] Understandably, by automatically identifying the type of device to be charged and matching the optimal charging protocol, it can adapt to the different charging needs of traditional and new devices, avoiding incompatibility issues when charging multiple devices. Matching a dedicated protocol enables 15W fast charging, shortening charging time and avoiding ineffective power supply. Precise adaptation can prevent device damage caused by overcharging, overcurrent, or voltage mismatch.

[0039] The device to be charged is charged according to the charging protocol, and the charging ends after a preset period of continuous charging.

[0040] Specifically, the mobile device charging module has a preset charging period of 30 minutes per session, after which it will automatically power off to prevent the device from being occupied for an extended period. If the user still needs to charge the device after the preset charging period, they can unplug the device and plug it back in to start the next charging session.

[0041] It should be noted that the seat system can charge up to 4 devices simultaneously (4 USB ports). To ensure fair use, users are limited to using a maximum of 2 USB ports for charging.

[0042] In some embodiments of this application, the sensor set mentioned in the foregoing embodiments is further described, such as... Figure 3 As shown, the sensor set may include a temperature sensor, an ultraviolet sensor, and an air quality sensor, all of which can be connected to the environmental monitoring module.

[0043] The sensor suite includes a temperature sensor to monitor ambient temperature and seat surface temperature, an ultraviolet (UV) sensor to monitor ambient UV intensity, and an air quality sensor (which can be a PM2.5 sensor) to monitor the size of PM2.5 particles in the air. Additionally, the sensor suite may include a humidity sensor and an atmospheric pressure sensor to monitor air humidity and atmospheric pressure, respectively.

[0044] Furthermore, ambient temperature, seat surface temperature, ambient ultraviolet radiation intensity, PM2.5 particle size, air humidity, atmospheric pressure, and the seat system's battery level are all transmitted to and displayed on the screen. The screen can be a 5-inch e-ink screen / CD color screen, which can be installed on the front of the seat back.

[0045] Based on this, the environmental monitoring module can provide daily health reminders, specifically for: When the temperature detected by the temperature sensor exceeds the high temperature threshold, the control display shows a high temperature warning message.

[0046] Specifically, when the ambient temperature detected by the temperature sensor is >35°C, a high-temperature warning can be issued, and the warning message will be displayed in the notification area of ​​the display screen. In hot weather, please take precautions against heatstroke.

[0047] When the ultraviolet intensity detected by the ultraviolet sensor exceeds the strong ultraviolet threshold, the control display screen will show a strong ultraviolet warning message.

[0048] Specifically, when the ultraviolet (UV) intensity detected by the UV sensor is greater than 7, a strong UV warning can be issued, and the warning will be displayed in the notification area of ​​the display screen. The ultraviolet radiation is strong, so it is recommended to take precautions against sun exposure.

[0049] When the PM2.5 value detected by the air quality sensor is greater than the first particle threshold, the control display screen will show an air quality warning message.

[0050] Specifically, when the PM2.5 value detected by the air quality sensor is greater than 75, a warning of poor air quality can be issued, and the message "Poor air quality, it is recommended to reduce outdoor activities" will be displayed in the prompt area of ​​the display screen interface.

[0051] When the temperature detected by the temperature sensor is within the comfortable temperature range, and the PM2.5 value detected by the air quality sensor is less than the second particle threshold, the control display shows a comfort prompt.

[0052] Specifically, when the temperature sensor detects a temperature of 20-26°C and the air quality sensor detects PM2.5 < 35, indicating comfortable weather, the display screen will show "Pleasant weather, suitable for outdoor activities" in the display area.

[0053] In some embodiments of this application, the seat temperature control module mentioned in the foregoing embodiments is further described. The seat temperature control module may include a first semiconductor chip disposed on the seat surface and a second semiconductor chip disposed on the seat back. The sensor set may also include a pressure sensor, which may be disposed below the seat surface, for sensing and identifying when a user sits on the seat. If the sensed weight is >10kg, it is determined that a user has sat on the seat; if the sensed weight is <10kg, it is determined that no user or object is placed on the seat. Based on this, the seat temperature control module can utilize semiconductor cooling / heating technology to control the seat temperature. Specifically, it can utilize the semiconductor Peltier effect for cooling by energizing and heating by reverse current.

[0054] More specifically, the seat temperature control module is connected to temperature and pressure sensors, and can be used for: When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and the temperature sensor detects that the ambient temperature is greater than the ambient high temperature threshold, the cooling mode is activated to reduce the seat surface temperature to below the seat surface cooling temperature threshold.

[0055] When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and the temperature sensor detects that the ambient temperature is less than the ambient low temperature threshold, the heating mode is activated to reduce the seat surface temperature to above the seat surface heating temperature threshold.

[0056] Specifically, the seat temperature control module automatically activates cooling / heating when a user sits down and under conditions of high temperature (e.g., above 32°C) / low temperature (e.g., below 5°C). Combined with the temperature sensor monitoring the seat surface temperature, it can adjust the seat surface temperature to a comfortable temperature (25-28°C). The seat temperature control module automatically turns off the temperature control function 30 seconds after the user leaves the seat.

[0057] Considering that the seat system may frequently activate the seat temperature control module under extreme weather conditions (such as above 35°C and below 0°C), in order to reduce the start-up and shutdown costs of the seat temperature control module, when the temperature sensor detects that the ambient temperature is greater than the ambient extreme high temperature threshold or less than the ambient extreme low temperature threshold, it is adjusted to the ready working state, so that the temperature can be directly controlled after a user sits down in the seat.

[0058] Among them, the environmental extreme high temperature threshold (35°C) is greater than the environmental high temperature threshold (32°C), and the environmental extreme low temperature threshold (0°C) is less than the environmental low temperature threshold (5°C).

[0059] Considering that the seat temperature control module may accidentally overheat or overcool, reducing the seat surface temperature and thus affecting the user experience, the power supply module can stop supplying power to the seat temperature control module when the seat surface temperature exceeds the overheating threshold or falls below the undercooling threshold to prevent temperature-related damage to the user (frostbite / heat injury). Furthermore, the seat system can also be equipped with a current protection mechanism; when an abnormal current is detected, a fuse can be used to cut off the power, thereby achieving an emergency stop and preventing further damage.

[0060] In some embodiments of this application, the sensor sets mentioned in the above embodiments are further described, with reference to... Figure 3 The sensor suite may also include an infrared sensor positioned above the seat. This infrared sensor can help determine whether a user is sitting in the seat (e.g., the heat radiation from an object on the seat is not human heat radiation), thus preventing seat hogging. The power supply module can be connected to the temperature sensor, pressure sensor, and infrared sensor. Specifically, the power supply module can also be used for: When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and the infrared radiation signal detected by the infrared sensor is the thermal radiation signal of the target user, the system is switched to normal power supply mode.

[0061] Understandably, when the pressure sensor detects weight and determines that a user is sitting in the seat, and the infrared radiation signal detected by the infrared sensor indicates that the object on the seat is a human body, it can be determined that the user is using the seat system. In this case, the power supply module can adjust to the normal power supply mode to meet the user's charging needs. If the pressure sensor detects weight and determines that a user is sitting in the seat, but the infrared radiation signal detected by the infrared sensor indicates that the object on the seat is not a human body, indicating that the item on the seat is too heavy, then the power supply module will only supply power to the highest priority environmental monitoring module and emergency call module, and will not supply power to the mobile device charging module.

[0062] Furthermore, during normal power supply, if the pressure value detected by the pressure sensor is not greater than the preset pressure threshold, or if the infrared radiation signal is a non-thermal radiation signal, the power supply mode is adjusted to low power consumption mode.

[0063] Understandably, when a user temporarily leaves, the pressure sensor will detect a pressure value that is not greater than a preset pressure threshold, and the infrared radiation signal will also be a non-thermal radiation signal. At this time, a low-power standby mode with the charging port retained can be maintained, so that the charging function can be restored immediately when the user returns to the seat, thereby reducing the start-up and shutdown costs of the mobile device charging module.

[0064] Furthermore, when the user leaves for an extended period of time, that is, after the power supply module has been in low-power mode for a preset waiting time, the power supply is stopped, and the seat temperature control module is controlled to stop working.

[0065] Understandably, after a preset waiting time in low-power mode, it indicates that the seat has been unoccupied for a long time. The power supply module can determine that the seat is occupied or the user has left. At this time, the functions of other modules except the environmental monitoring module and the emergency call module can be automatically turned off to reduce unnecessary power consumption.

[0066] Furthermore, the power supply module can also be equipped with a nighttime energy-saving mode, which specifically turns off the functions of all modules except the lighting module and the emergency call module when no user is using the seat at night (22:00-6:00).

[0067] In some embodiments of this application, the above-mentioned seating system may also have a built-in data management module. The data management module can record the number of users per day, usage records during peak hours (such as 18:00-20:00 in the evening), average usage time, and charging service usage rate, and upload these recorded data to the cloud system. The cloud system can perform optimization analysis based on these recorded data to facilitate the addition of seats with high usage rates and the reduction or adjustment of seats with low usage rates.

[0068] In some embodiments of this application, the emergency call module mentioned in the above embodiments is further described. The emergency call module may include a seat flashing light, a buzzer, a voice broadcast unit, and an emergency button located on the inside of the seat armrest. The emergency button is 10cm in diameter, easy to press, red, and conspicuous. Based on this, the emergency call module can be used for: In response to the emergency button being pressed for a preset duration, an emergency call is executed.

[0069] The emergency call actions may include controlling the seat flashing light to flash, controlling the buzzer to sound an alarm, controlling the voice broadcast unit to play an alarm voice, controlling the display screen to show the emergency call information, and reporting the emergency information to the superior system.

[0070] Specifically, if a user accidentally presses the emergency button, it will not be considered an emergency call because the button is pressed for less than the preset duration. When the user needs emergency assistance, they can press and hold the emergency button for 3 seconds. The seat's LED light will flash red, the buzzer will sound an alarm "beep beep beep," the voice broadcast unit will play an alarm message saying "Emergency call sent, rescuers are on their way," and the display screen will show the emergency call information in full brightness, maximizing the chances of getting help. In addition, if the seat is equipped with a camera, it can automatically record video in this emergency and provide it to the rescue team for more efficient rescue work. At the same time, the emergency call module can also send emergency information to the cloud management platform (such as the park management office) and the handheld terminals of nearby patrol personnel, facilitating the faster arrival of nearby rescue forces at the scene. The emergency information can include the precise location of the seat system, such as GPS coordinates or seat number.

[0071] Based on this, to further enhance the health care function, the health monitoring module mentioned in the aforementioned embodiments can be integrated with, for example... Figure 3 The heart rate sensor and blood pressure sensor are connected as shown. Both the heart rate sensor and blood pressure sensor can be installed in the armrests of the seat. Users can freely choose to measure heart rate or blood pressure when using the seat system. Based on this, the health monitoring module can be used for: When the heart rate sensor detects an abnormal heart rate in the target user, it controls the voice broadcast unit to play a heart rate abnormality prompt voice and controls the display screen to display heart rate abnormality help interaction information. If no feedback information on heart rate abnormality help interaction information is received after a preset interaction waiting time, it drives the emergency call module to execute an emergency call action.

[0072] Specifically, the heart rate sensor can measure the user's heart rate. When an abnormal heart rate is detected, it can display "heart rate too fast / heart rate too slow" on the screen and highlight the heart rate abnormality help interaction message "Your heart rate is abnormal, do you need help?" along with the highlighted options "I'm fine" and "Need help". If the user is conscious and mobile, they can interact with this heart rate abnormality help interaction message. However, if the user does not receive feedback after a preset interaction waiting time (or clicks "Need help"), it can be identified that the user may be confused or experiencing mobility issues (or require rescue). In this case, the emergency call module can be activated to execute an emergency call to minimize the risk of tragedy.

[0073] When the blood pressure sensor detects an abnormal blood pressure in the target user, it controls the voice broadcast unit to play a blood pressure abnormality prompt voice and controls the display screen to display blood pressure abnormality help interaction information. If no feedback information on blood pressure abnormality help interaction information is received after a preset interaction waiting time, it drives the emergency call module to execute an emergency call action.

[0074] Specifically, the blood pressure sensor can measure the user's blood pressure value. When an abnormal blood pressure value is detected, it can display "High blood pressure / Low blood pressure" on the screen and highlight the blood pressure abnormality help interaction message "Your blood pressure is abnormal, do you need help?" along with the highlighted options "I'm fine" and "Need help". If the user is conscious and mobile, they can interact with this blood pressure abnormality help interaction message. However, if the user does not receive feedback on the heart rate abnormality help interaction message after a preset interaction waiting time (or clicks "Need help"), it can be identified that the user may be confused or have difficulty moving (or need rescue), requiring assistance. In this case, the emergency call module can be activated to execute an emergency call to minimize the possibility of tragedy.

[0075] Furthermore, considering that users may accidentally trigger an emergency call by accidentally touching the emergency button or selecting the rescue option over a long period of time, a prominent option to cancel the emergency call service can be set on the display screen. Then, after hearing the buzzer alarm or seeing the emergency call information highlighted on the display screen, users can click the option to cancel the emergency call to cancel the emergency call status.

[0076] Finally, it should be noted that in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.

[0077] The various embodiments in this specification are described in a progressive manner. Each embodiment focuses on the differences from other embodiments. The various embodiments can be combined as needed, and the same or similar parts can be referred to each other.

[0078] The above description of the disclosed embodiments enables those skilled in the art to make or use this application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of this application. Therefore, this application is not to be limited to the embodiments shown herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A seating system, characterized in that, It includes a seat, a power supply module, a mobile device charging module, an environmental monitoring module, an emergency call module, a lighting module, and a seat temperature control module. The power supply module is used for: Continuously supply power to the environmental monitoring module and the emergency call module; When a signal indicating that the seat has been occupied is received, power is supplied to the charging module of the mobile device; When the environmental monitoring module receives an extreme weather signal, it supplies power to the seat temperature control module. When the environment monitoring module detects a darkness signal, it supplies power to the lighting module. When the energy storage capacity of the seat system is less than the energy storage threshold, power supply to the seat temperature control module and the mobile device charging module is stopped.

2. The seating system according to claim 1, characterized in that, The mobile device charging module is used for: When a device to be charged is detected, the device type of the device to be charged is identified, and the charging protocol that matches the device type is determined. The device to be charged is charged according to the charging protocol, and the charging ends after a preset charging period.

3. The seating system according to claim 2, characterized in that, The mobile device charging module includes a wireless charging module disposed on both sides of the armrests of the seat, and a USB charging module embedded in the back of the seat.

4. The seating system according to claim 1, characterized in that, It also includes a sensor set and a display screen, the sensor set including a temperature sensor, an ultraviolet sensor and an air quality sensor; The environmental monitoring module is used for: When the temperature detected by the temperature sensor is greater than the high temperature threshold, the display screen is controlled to show a high temperature warning message; When the ultraviolet intensity detected by the ultraviolet sensor is greater than the strong ultraviolet threshold, the display screen is controlled to show a strong ultraviolet warning message. When the PM2.5 value detected by the air quality sensor is greater than the first particle threshold, the display screen is controlled to show air quality alert information. When the temperature detected by the temperature sensor is within the comfortable temperature range, and the PM2.5 value detected by the air quality sensor is less than the second particle threshold, the display screen is controlled to display a comfort prompt message.

5. The seating system according to claim 4, characterized in that, The seat temperature control module includes a first semiconductor chip disposed on the seat surface and a second semiconductor chip disposed on the seat back. The seat temperature control module is used for: When the seat temperature control module is powered on, it monitors the surface temperature of the seat based on the temperature sensor, and then powers the first and second semiconductor chips through the semiconductor Peltier effect to regulate the temperature.

6. The seating system according to claim 5, characterized in that, The sensor set also includes a pressure sensor disposed under the seat surface, and the seat temperature control module is further used for: When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and when the temperature sensor detects that the ambient temperature is greater than the ambient high temperature threshold, the cooling mode is activated to reduce the seat surface temperature of the seat to below the seat surface cooling temperature threshold. When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and the temperature sensor detects that the ambient temperature is less than the ambient low temperature threshold, the heating mode is activated to reduce the seat surface temperature to above the seat surface heating temperature threshold. When the temperature sensor detects that the ambient temperature is greater than the ambient extreme high temperature threshold or less than the ambient extreme low temperature threshold, it adjusts to the ready working state, wherein the ambient extreme high temperature threshold is greater than the ambient high temperature threshold, and the ambient extreme low temperature threshold is less than the ambient low temperature threshold.

7. The seating system according to claim 6, characterized in that, The power supply module is also used for: When the seat surface temperature is greater than the overheating temperature threshold or less than the overcooling temperature threshold, power supply to the seat temperature control module is stopped.

8. The seating system according to claim 6, characterized in that, The sensor set also includes an infrared sensor disposed above the seat, and the power supply module is further used for: When the pressure value detected by the pressure sensor is greater than the preset pressure threshold, and the infrared radiation signal detected by the infrared sensor is the thermal radiation signal of the target user, the system is adjusted to normal power supply mode. During normal power supply of the power supply module, if the pressure value detected by the pressure sensor is not greater than the preset pressure threshold, or if the infrared radiation signal is a non-thermal radiation signal, the power supply mode is adjusted to low power consumption mode. After the power supply module has been in the low-power power supply mode for a preset waiting time, the power supply is stopped, and the seat temperature control module is controlled to stop working.

9. The seating system according to claim 4, characterized in that, The emergency call module includes a seat flashing light, a buzzer, a voice broadcast unit, and an emergency button located inside the armrest of the seat. The emergency call module is used for: In response to the operation of pressing the emergency button for a preset time, an emergency call action is executed, wherein the emergency call action includes controlling the seat flashing light to flash, controlling the buzzer to sound an alarm, controlling the voice broadcast unit to play an alarm voice, controlling the display screen to display emergency call information, and reporting the emergency information to the superior system.

10. The seating system according to claim 9, characterized in that, It also includes a health monitoring module, and the sensor set further includes a heart rate sensor and a blood pressure sensor disposed on the armrest of the seat. The health monitoring module is used for: When the heart rate sensor detects an abnormal heart rate in the target user, it controls the voice broadcast unit to play a heart rate abnormality prompt voice and controls the display screen to display heart rate abnormality help interaction information. If no feedback information of the heart rate abnormality help interaction information is received after a preset interaction waiting time, it drives the emergency call module to execute the emergency call action. When the blood pressure sensor detects an abnormal blood pressure in the target user, it controls the voice broadcast unit to play a blood pressure abnormality prompt voice and controls the display screen to display blood pressure abnormality help interaction information. If no feedback information of the blood pressure abnormality help interaction information is received after a preset interaction waiting time, it drives the emergency call module to execute the emergency call action.