CN117742427A - Intelligent post system - Google Patents

Intelligent post system Download PDF

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Publication number
CN117742427A
CN117742427A CN202410190288.7A CN202410190288A CN117742427A CN 117742427 A CN117742427 A CN 117742427A CN 202410190288 A CN202410190288 A CN 202410190288A CN 117742427 A CN117742427 A CN 117742427A
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module
subsystem
control
intelligent
post system
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CN202410190288.7A
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CN117742427B (en
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陈磊
孙琦
赵洪卫
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Beijing Midea Overseas Engineering and Technology Co Ltd
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Beijing Midea Overseas Engineering and Technology Co Ltd
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Abstract

The embodiment of the application provides an intelligent post system, intelligent post system includes: the detection subsystem is configured to monitor environmental parameters in real time to obtain environmental parameter values; the control subsystem is configured to control the working state of the related subsystem included in the intelligent post system according to the environmental parameter value; a service providing subsystem configured to provide a plurality of service types; and a power subsystem configured to power the related subsystems included in the intelligent post system. By adopting the multifunctional intelligent energy-saving comfortable sharing post stand convenient for people, the integration of one minute of high convenience for people can be met, and the self-sufficiency, energy saving and power interruption or unstable power intrusion can be avoided.

Description

Intelligent post system
Technical Field
The application relates to intelligent post field, and specifically, the embodiment of the application relates to an intelligent post system.
Background
The applicant's Ningbo Ruiyuan Tianke new energy materials limited company provides a patent application with the patent application number of CN202021815161.3, and the patent name of ' a multifunctional convenient post house easy to assemble ', wherein the post house disclosed in the application comprises a connecting column, a solar panel, a door body and a control device, wherein the solar panel is arranged at the top of the connecting column, the door body is detachably arranged between the connecting columns, the control device is arranged at the left side of the bottom of the solar panel, clamping grooves are formed in two-phase viewing sides of the connecting columns, and transverse connecting rods and longitudinal connecting rods are inserted between the connecting columns through the clamping grooves. Through the structural design, the installation period can be shortened; the solar panel can be self-sufficient, and resources are saved. The technical scheme of the patent application focuses on the fact that the structure is easy to assemble, and although the solar panel is additionally arranged to perform self-sufficiency, how the solar panel is multifunctional and shared is not shown, whether comfort can be met is not shown, and intelligence is not realized.
Patent application number is CN201920807583.7, and application name is multifunctional shared convenient post house, and the multifunctional shared convenient post house comprises a vending machine, a cabinet body abutted to the vending machine, an information display screen arranged in the cabinet body and two shared equipment sets. The scheme integrates the vending machine and the sharing equipment with a plurality of different functions into a whole to provide more daily convenience requirement services. The technical solution of this patent application, although providing a multi-functional sharing method, is generally only a vending machine, and the functions that can be provided are very limited, without a structurally independent space, and at the same time cannot satisfy the use of the vending machine in the event of a power failure.
Disclosure of Invention
An aim of the embodiment of the application is to provide an intelligent post system, and the multifunctional intelligent convenient energy-saving comfortable sharing post that adopts this application embodiment to provide can satisfy the integration of a high convenient to use people, can realize again that the power consumption is self-sufficient, energy-conserving and avoid having a power failure or the unstable invasion of electric power. The invention is provided with a plurality of sensors, and detects a plurality of influencing factors (elements) of the environment in real time, thereby intelligently controlling the whole environment.
In a first aspect, an embodiment of the present application provides an intelligent post system, the intelligent post system includes: the detection subsystem is configured to monitor environmental parameters in real time to obtain environmental parameter values, and uses diversified sensors to detect various influencing factors of the environment in real time, including irradiance, illuminance, temperature, humidity, carbon dioxide concentration and post personnel flow; the control subsystem is configured to control the working states of related subsystems included in the intelligent post system according to the environmental parameter values, and the intelligent control of the post system is finally achieved by selecting a regulating method with minimum energy consumption and minimum environmental intervention through comprehensively optimized environmental regulation after combining various influencing factors; a service providing subsystem configured to provide a plurality of service types; and a power subsystem configured to power the related subsystems included in the intelligent post system.
In some embodiments, the detection subsystem further comprises: an irradiance detection module configured to monitor an irradiance intensity of the sun and provide the irradiance intensity to the control subsystem; the power subsystem further comprises: a solar photovoltaic module configured to convert solar energy into electrical energy; and an energy storage module configured to store excess electrical energy when the solar photovoltaic module generates electricity; the control subsystem is configured to calculate the generated energy of the solar photovoltaic module according to the irradiation intensity; the power subsystem further comprises: and the power dispatching module is configured to automatically dispatch power according to the power demand, the generated energy and the redundant electric energy of the intelligent post system.
In some embodiments, the detection subsystem further comprises: the illuminance detection module is configured to monitor the illuminance intensity in the site and transmit the measurement result to the control subsystem in real time; and a temperature detection module configured to monitor a temperature within the site; the service providing subsystem further comprises: the shading and heat insulation module is configured to regulate and control illumination and heat inside and outside the intelligent station so as to block external intense illumination and heat invasion; the control subsystem further comprises: and the light shielding and heat insulating module is controlled and configured to automatically adjust the working condition of the light shielding and heat insulating module according to the illumination intensity and the temperature.
In some embodiments, the shade and insulation module is configured to shade and insulate using both a shade and an insulation coating, the shade adjusting the shade as needed to block different intensity illumination, the insulation coating reflecting and absorbing heat to block heat transfer, the shade and insulation module control being configured to automatically adjust the shade of the shade and automatically adjust the intensity of radiation entering the room.
In some embodiments, the detection subsystem further comprises: a humidity detection module configured to monitor humidity within the site; the control subsystem further comprises: and the humidity control module is configured to regulate and control the humidity in the station according to the humidity and/or the user demand.
In some embodiments, the humidity control module is configured to automatically adjust the operating state of the humidification/dehumidification device based on the humidity and a user setting.
In some embodiments, the detection subsystem further comprises: a carbon dioxide concentration detection module configured to monitor a carbon dioxide concentration within a site; the service providing subsystem further comprises: an air purification module configured to purify air within the smart site; the control subsystem further comprises: and the air purification module is controlled and configured to automatically adjust the working condition of the air purification module according to the carbon dioxide concentration, automatically start or close a fresh air system and automatically adjust the purification amount of the air purification module.
In some embodiments, the air purification module performs air purification using both physical filtration and chemical adsorption.
In some embodiments, the service providing subsystem further comprises: automatic sell module, express delivery transceiver module, district group purchase module, clothing recovery module and unmanned vehicles.
In some embodiments, the control subsystem communicates with the detection subsystem, the service providing subsystem, and the power subsystem over a wireless network; the control subsystem communicates with the intelligent equipment of the user through a wireless network to realize remote control and management.
The diversified sensor is matched with various actuators, and through detection of various environmental factors, the sensor is not regulated by a single-factor single-regulation means, is not regulated linearly and directly, but is comprehensively and optimally regulated after combining various factors, and finally achieves the effect of intelligent control. The intelligent control realizes the minimum energy consumption, the minimum environmental intervention and the optimal regulation and control effect.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.
FIG. 1 is one of the block diagrams of the intelligent post system provided in the embodiments of the present application;
FIG. 2 is a second block diagram of the intelligent post system according to the embodiment of the present application;
FIG. 3 is a block diagram of a detection subsystem provided in an embodiment of the present application;
FIG. 4 is a block diagram of a control subsystem provided in an embodiment of the present application;
FIG. 5 is a block diagram of an execution subsystem provided in an embodiment of the present application;
FIG. 6 is a block diagram of a flow-through subsystem provided in an embodiment of the present application;
FIG. 7 is a block diagram of the components of a power subsystem according to an embodiment of the present application;
FIG. 8 is a block diagram of a display subsystem according to an embodiment of the present application;
fig. 9 is a block diagram of a communication subsystem according to an embodiment of the present application.
Detailed Description
The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.
It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only to distinguish the description, and are not to be construed as indicating or implying relative importance.
Referring to fig. 1, fig. 1 provides an intelligent post system according to an embodiment of the present application, the intelligent post system includes: detection subsystem 110, control subsystem 120, service providing subsystem 130, and power subsystem 140.
The detection subsystem 110 is configured to monitor environmental parameters in real time, obtain environmental parameter values, and detect in real time, using various sensors, various influencing factors of the environment, including irradiance, illuminance, temperature, humidity, carbon dioxide concentration, and post personnel flow.
The control subsystem 120 is configured to control the working states of related subsystems included in the intelligent post system according to the environmental parameter values, select a regulating method with minimum energy consumption and minimum environmental intervention by combining comprehensive optimized environmental regulation after various influencing factors, realize the optimal regulating effect and finally achieve the intelligent control of the post system.
The service providing subsystem 130 is configured to provide a plurality of service types.
A power subsystem 140 configured to power the associated subsystems included in the intelligent post system.
It should be noted that, the intelligent post system according to some embodiments of the present application further includes, in addition to the subsystems of fig. 1, a display subsystem 150 and an interaction subsystem 160 as shown in fig. 2, where the service providing subsystem 130 further includes an execution subsystem 170 and a circulation subsystem 180. It will be appreciated that the intelligent post system of some embodiments of the present application further includes a communication subsystem as shown in fig. 9. For example, the interaction subsystem includes a parameter display module, a mode input module, and a human-computer interaction module for displaying environmental parameters, receiving mode inputs from a user, and interacting with the user. For example, the execution subsystem includes an air purification module, a light shielding and heat insulation module, a cooling/heating module, a humidification/dehumidification module, an air purification module, and the like for performing environmental regulation. For example, the display subsystem comprises a large screen display module, an advertisement putting module, a laser projection module and an announcement display module, and is used for displaying various information. For example, the circulation subsystem comprises an automatic selling module, an express receiving and sending module, a community group purchase module, a clothes recycling module and an unmanned vehicle, and provides various services. For example, the power subsystem comprises a solar photovoltaic module, a power supply module, an energy storage module and a charging module, and is responsible for power supply of a station.
The subsystems are exemplarily described below in connection with related examples and fig. 3-9.
As shown in fig. 3, in some embodiments of the present application, detection subsystem 110 illustratively includes: irradiance monitoring module 111, illuminance detection module 112, humidity detection module 113, carbon dioxide concentration detection module 114, and temperature detection module 115.
In some embodiments of the present application, the irradiance detection module is primarily responsible for monitoring the irradiance of the sun in order to calculate the power generation of the solar photovoltaic module, thereby providing reference data for the power subsystem. The module generally adopts an irradiance sensor, can accurately measure the irradiation intensity of the sun, and transmits the measurement result to the control subsystem in real time.
In some embodiments of the present application, the illuminance detection module is primarily responsible for monitoring the intensity of illumination within the site. The module generally adopts an illuminance sensor, can accurately measure the illumination intensity in a site, and transmits a measurement result to a control subsystem in real time. In addition, the module can also monitor illumination changes in the site, such as changes in sunlight and artificial light, to provide reference data for the control subsystem to facilitate adjustment of the operation of the shade and insulation module and the lighting module.
In some embodiments of the present application, the temperature detection module is primarily responsible for monitoring the temperature within the site. The module generally adopts a temperature sensor, can accurately measure the temperature in the site, and transmits the measurement result to the control subsystem in real time. In addition, the module can also monitor temperature changes within the site, such as changes in outdoor temperature and indoor temperature, to provide reference data for the control subsystem to facilitate regulating the operation of the temperature control module (cooling/heating module).
In some embodiments of the present application, the humidity detection module is primarily responsible for monitoring humidity within the site. The module generally adopts a humidity sensor, can accurately measure the humidity in the site, and transmits the measurement result to the control subsystem in real time. In addition, the module can also monitor humidity changes within the site, such as changes in outdoor humidity and indoor humidity, to provide reference data for the control subsystem to facilitate regulating the operation of the humidity control module (humidification/dehumidification module).
In some embodiments of the present application, the carbon dioxide concentration detection module is primarily responsible for monitoring the carbon dioxide concentration within the site. The module generally adopts a carbon dioxide sensor, can accurately measure the carbon dioxide concentration in the site, and transmits the measurement result to the control subsystem in real time. In addition, the module may monitor changes in carbon dioxide concentration within the site to provide reference data for the control subsystem to facilitate regulating operation of the air purification module.
As shown in fig. 4, in some embodiments of the present application, control subsystem 120 illustratively includes: a shading and heat insulation control module 121, an illumination control module 122, a temperature control module 123, a humidity control module 124, and an air purification control module 125.
In some embodiments of the present application, the shading and heat insulation control module is responsible for automatically adjusting the working condition of the shading and heat insulation module according to the data of the illuminance detection module and the temperature detection module, automatically adjusting the shading degree of the electric control glass, automatically adjusting the irradiation intensity entering the room, and the like.
In some embodiments of the present application, the lighting control module is responsible for automatically adjusting the working condition of the lighting module according to the data of the illuminance detection module, such as automatically turning on or off the lighting lamp, automatically adjusting the brightness of the lighting lamp, and the like.
In some embodiments of the present application, the temperature control module controls the working condition of the temperature control module, such as automatically opening or closing the refrigeration device, automatically adjusting the refrigeration capacity of the refrigeration device, automatically opening or closing the heating device, automatically adjusting the heating capacity of the heating device, and the like, which are responsible for the automatic adjustment according to the data of the temperature detection module.
In some embodiments of the present application, the humidity control module controls the working condition of the humidity control module, such as automatically turning on or off the humidifier, automatically adjusting the humidification amount of the humidifier, automatically turning on or off the dehumidifier, automatically adjusting the dehumidification amount of the dehumidifier, etc., which are responsible for the data of the humidity detection module.
In some embodiments of the present application, the air purification control module is responsible for automatically adjusting the working condition of the air purification module, such as automatically opening or closing a fresh air system, automatically adjusting the purification amount of the air purifier, and the like, according to the data of the carbon dioxide concentration detection module.
As shown in fig. 5, in some embodiments of the present application, the execution subsystem 170 illustratively includes: an air purification module 171, a light shielding and heat insulation module 172, a cooling/heating module 173, and a humidification/dehumidification module 174.
In some embodiments of the application, the air purification module is mainly responsible for purifying air in the intelligent station, and can effectively remove dust, viruses, bacteria, pollen, smoke and other harmful substances in the air, so that the air in the intelligent station is more fresh. Air purification modules typically employ both physical filtration and chemical adsorption for air purification. The physical filtration is mainly to isolate particles in the air through a high-efficiency filter screen; the chemical adsorption is to adsorb the harmful gas in the air by activated carbon or other adsorption materials. In addition, the air purification module can kill viruses and bacteria in the air through ultraviolet irradiation or negative ion technology, so that the cleanliness of the air is further improved.
In some embodiments of the application, the shading and heat insulation module is mainly responsible for regulating and controlling the illumination and heat inside and outside the intelligent station, and can effectively block the external strong illumination and heat invasion, so that the environment in the intelligent station is more comfortable. The shading and heat insulation module generally performs shading and heat insulation by adopting two modes of shading curtains and heat insulation paint. The shading degree of the shading curtain can be adjusted according to the requirement, so that illumination with different intensities is blocked; the heat-insulating coating can prevent heat transfer by reflecting and absorbing heat. In addition, the shading and heat insulation module can further improve shading and heat insulation effects by installing double-layer glass windows or using heat insulation materials.
In some embodiments of the present application, the cooling/heating module is mainly responsible for controlling the temperature in the smart site, and it can automatically cool or heat according to the environment and the user's requirements, so that the temperature in the smart site is always in a comfortable range. The refrigerating/heating module generally adopts two devices, namely an air conditioner and an electric heater to regulate and control the temperature. The air conditioner can refrigerate in summer, so that the indoor temperature is reduced; the electric heater can heat in winter to raise indoor temperature. In addition, the refrigerating/heating module can automatically adjust the working state of the refrigerating/heating equipment according to the ambient temperature and the user set value through the intelligent temperature control system, so that accurate temperature control is realized.
In some embodiments of the present application, the humidification/dehumidification module is mainly responsible for regulating and controlling humidity in the smart site, and it can automatically humidify or dehumidify according to the environment and the user requirements, so that the humidity in the smart site is always in a proper range. The humidity control module generally adopts two devices, namely a humidifier and a dehumidifier to regulate and control the humidity. The humidifier can increase air humidity in a dry environment to provide a comfortable humidity environment; the dehumidifier can reduce the air humidity in a humid environment and prevent various problems caused by the excessive humidity. In addition, the humidity control module can automatically adjust the working state of the humidifying/dehumidifying equipment according to the ambient humidity and the user set value through an intelligent humidity control system, so that accurate humidity control is realized.
As shown in fig. 6, in some embodiments of the present application, power subsystem 140 illustratively includes: a solar photovoltaic module 141, an energy storage module 142, and a power dispatching module 143.
In some embodiments of the present application, the solar photovoltaic module is the primary energy supply of the power subsystem responsible for converting solar energy into electrical energy. The module generally includes a solar panel and an inverter. The solar panel is responsible for converting solar energy into direct current, and the inverter is responsible for converting direct current into alternating current and delivering power to various functional modules.
In some embodiments of the present application, the energy storage module is another important component of the power subsystem, responsible for providing the power supply when the solar photovoltaic module is generating insufficient power. The module generally adopts a storage battery, and can store redundant electric energy for later use when the solar photovoltaic module generates electricity.
In some embodiments of the present application, the power scheduling module is responsible for automatically allocating power according to the power requirements of the various functional modules and the power supply conditions of the power subsystem. The module can accurately calculate the power consumption of various functional modules, and reasonably distributes power according to the power supply condition of the power subsystem so as to ensure the normal operation of the whole intelligent station.
The control flow of the above subsystem is described below in connection with several examples.
For example, in some embodiments of the present application, the detection subsystem further comprises: an irradiance detection module configured to monitor an irradiance intensity of the sun and provide the irradiance intensity to the control subsystem; the power subsystem further comprises: a solar photovoltaic module configured to convert solar energy into electrical energy; and an energy storage module configured to store excess electrical energy when the solar photovoltaic module generates electricity; the control subsystem is configured to calculate the generated energy of the solar photovoltaic module according to the irradiation intensity; the power subsystem further comprises: and the power dispatching module is configured to automatically dispatch power according to the power demand, the generated energy and the redundant electric energy of the intelligent post system.
For example, in some embodiments of the present application, an illuminance detection module configured to monitor the illuminance within a site and transmit the measurement to a control subsystem in real time; and a temperature detection module configured to monitor a temperature within the site; the service providing subsystem further comprises: the shading and heat insulation module is configured to regulate and control illumination and heat inside and outside the intelligent station so as to block external intense illumination and heat invasion; the control subsystem further comprises: and the light shielding and heat insulating module is controlled and configured to automatically adjust the working condition of the light shielding and heat insulating module according to the illumination intensity and the temperature.
For example, in some embodiments of the present application, the shade and insulation module is shade and insulated using both a shade that adjusts the shade level as needed to block different intensities of light and an insulation coating that reflects and absorbs heat to block heat transfer, the shade and insulation module control is configured to automatically adjust the shade level of the shade and automatically adjust the intensity of radiation entering the room.
For example, in some embodiments of the present application, the detection subsystem further comprises: a humidity detection module configured to monitor humidity within the site; the control subsystem further comprises: and the humidity control module is configured to regulate and control the humidity in the station according to the humidity and/or the user demand. For example, in some embodiments of the present application, the humidity control module is configured to automatically adjust the operating state of the humidification/dehumidification device based on the humidity and a user setting.
For example, in some embodiments of the present application, the detection subsystem further comprises: a carbon dioxide concentration detection module configured to monitor a carbon dioxide concentration within a site; the service providing subsystem further comprises: an air purification module configured to purify air within the smart site; the control subsystem further comprises: and the air purification module is controlled and configured to automatically adjust the working condition of the air purification module according to the carbon dioxide concentration, automatically start or close a fresh air system and automatically adjust the purification amount of the air purification module. For example, in some embodiments of the present application, the air purification module performs air purification using both physical filtration and chemical adsorption.
For example, as shown in fig. 7, in some embodiments of the present application, the service providing subsystem further comprises: a vending module 181, an express delivery receiving and sending module 182, a cell group purchase module 183, a clothing recycling module 184, and an unmanned vehicle 185.
The circulation subsystem of some embodiments of the present application is mainly used for providing various services. The automatic vending module is mainly used for automatically vending commodities such as beverages, snacks and the like, and automatically completing checkout by automatically identifying the commodities selected by a customer; the express delivery receiving and sending module is mainly used for receiving and sending express delivery, supporting to sweep and stack up goods to be delivered, receiving the receiving information of the delivered goods, automatically sending receiving short messages, receiving codes or receiving two-dimensional codes and the like to a receiver, and simultaneously providing convenient and fast pickup service for the receiver through modes of sweeping, inputting the receiving codes, identifying the faces, identifying the mobile phone numbers and the like; the community group purchase module is mainly used for community resident group purchase; the clothes recovery module is mainly used for recovering clothes, meanwhile, the clothes recovery support two modes of gratuitous donation and gratuitous recovery, the system automatically records the gratuitous donation clothes and the gratuitous recovery clothes, and for gratuitous donation clothes, the gratuitous recovery clothes can be taken away by a required person in gratuitous mode, and the gratuitous recovery clothes can be taken away only by paying equivalent purchase cost. The system does not disclose the information that the clothes are purchased or paid for removal, and privacy protection is provided for personnel needing the clothes; the unmanned aerial vehicle is mainly used for delivering commodities, for specifying small-sized articles to be delivered to a user, after the delivered user confirms that the small-sized articles can be received, the express delivery system enables the articles to pass through an automatic delivery warehouse and to be placed on an unmanned aerial vehicle at a delivery position, meanwhile, the address of the receiver, which is detailed to a house number, is sent to the unmanned aerial vehicle at the delivery position, the unmanned aerial vehicle automatically performs path planning, and the articles to be delivered are delivered to the address (a home gate) of the receiver. And calling the receiver through a telephone, and after the receiver confirms the receiving and takes away the goods through the APP, automatically planning a travelling path by the unmanned trolley and returning to the convenience post. If the consignee does not confirm the receiving goods continuously, the unmanned trolley automatically gives an alarm to an administrator to prompt the consignee to manually process or contact the receiving goods.
The circulation subsystem is an important component in the intelligent site and mainly comprises an automatic vending module, an express receiving and transmitting module, a community group purchase module, a clothes recycling module, an unmanned vehicle and the like and is used for providing various services. These modules will be described in detail below.
In some embodiments of the present application, vending modules are used primarily for vending beverage, snack food, and like items. The automatic commodity checking machine automatically checks out by automatically identifying commodities selected by customers, and provides convenient and quick shopping experience. The automatic vending module adopts an advanced commodity identification technology, can accurately identify commodities selected by customers, automatically completes checkout through a networked payment system, and greatly improves shopping efficiency. In addition, the automatic vending module is also provided with an intelligent inventory management system, so that the sales and inventory conditions of the commodities can be monitored in real time, and the commodities can be automatically replenished, so that the sufficiency of the commodities is ensured.
In some embodiments of the present application, the express delivery receiving and sending module is mainly used for receiving and sending express delivery. The goods to be delivered are placed in a supporting mode through scanning, receiving goods receiving information of the delivered goods, automatically sending goods receiving short messages, goods receiving codes or goods receiving two-dimensional codes to a receiver, and simultaneously providing convenient goods taking service for the receiver through modes of scanning codes, inputting goods taking codes, face recognition, mobile phone number recognition and the like. The express receiving and transmitting module adopts advanced article identification and tracking technology, can accurately track receiving and transmitting conditions of articles, and provides safe and reliable express service.
In some embodiments of the present application, the cell group purchase module is primarily used for cell resident group purchases. The system collects group purchase demands of residents through a networking order system, automatically organizes group purchase activities and provides convenient and quick group purchase service. The community group purchase module adopts a big data analysis technology, and can automatically recommend proper group purchase goods according to shopping habits and demands of residents, thereby improving the success rate and satisfaction of group purchase. In addition, the district group purchase module is also provided with an intelligent distribution system, so that a distribution route can be automatically planned according to the distribution address of the group purchase order, and the distribution efficiency is improved.
In some embodiments of the present application, the laundry recycling module is primarily used for recycling laundry. The system supports two modes of gratuitous donation and gratuitous recovery, and automatically records gratuitous donation clothes and gratuitous recovery clothes, and for gratuitous donation clothes, the gratuitous recovery clothes can be taken away by a required person gratuitous, and the gratuitous recovery clothes can be taken away only by paying equivalent purchase cost. The system does not disclose information that the clothes are purchased or paid for removal, and provides privacy protection for personnel in need of the clothes. The clothes recovery module adopts advanced clothes identification and tracking technology, can accurately record the recovery and taking-off conditions of clothes, and provides safe and reliable clothes recovery service.
In some embodiments of the present application, the unmanned aerial vehicle is primarily used for delivery of goods, for specifying small items to be delivered to the home, after the deliveree confirms that the items can be received, the express delivery system places the items on the unmanned aerial vehicle at the delivery location through the automatic delivery warehouse, simultaneously sends the address of the receiver to the house number in detail to the unmanned aerial vehicle at the delivery location, the unmanned aerial vehicle automatically performs path planning, and delivers the items to be delivered to the receiver address (home gate). The unmanned vehicle adopts advanced automatic driving technology and path planning algorithm, and can accurately and safely convey the articles to the designated address. After delivery, the unmanned vehicle calls the receiver through a telephone, and after the receiver confirms the receiving and takes away goods through the APP, the unmanned vehicle automatically plans the travelling path and returns to the convenience post. If the consignee does not confirm the receiving goods continuously, the unmanned trolley automatically gives an alarm to an administrator to prompt the consignee to manually process or contact the receiving goods. In this embodiment, automatic selling module, express delivery transceiver module, clothing recovery module, district group purchase module are through inside article transfer device, and the sharing uses automatic shipment storehouse. Like this, automatic selling module, express delivery transceiver module, clothing recovery module, district group purchase module all accessible automatic shipment storehouse, will need the article of transporting to reach the assigned address through unmanned dolly, realize unmanned dolly to automatic selling, clothing is retrieved and the support of district group purchase.
In some embodiments of the present application, the circulation subsystem not only provides convenient and fast service, but also implements unmanned and automatic operations through intelligent technology, thereby greatly improving service efficiency and user experience. Meanwhile, the circulation subsystem also adopts advanced article tracking technology and data protection measures, so that the security of the service and the privacy of the user are ensured. Along with the development of science and technology, the functions of the circulation subsystem are more and more powerful, so that the intelligent site is more intelligent and humanized.
In some embodiments of the present application, the interaction subsystem mainly comprises a parameter display module, a mode input module and a man-machine interaction module (not shown in the figure), and is used for displaying environmental parameters, receiving mode input of a user and interacting with the user. The interaction subsystem is an important component of the intelligent site and mainly comprises a parameter display module, a mode input module and a man-machine interaction module, and is used for displaying environment parameters, receiving mode input of a user and interacting with the user. The following is a detailed description of these three modules.
In some embodiments of the present application, the parameter display module is a core part of the interaction subsystem, and is mainly used for displaying environmental parameters. The intelligent display system based on the internet of things can receive and process environmental parameter data from various sensors, such as temperature, humidity, air pressure, air quality, illumination intensity and the like in real time, and display the data on a screen in a graphical mode so as to provide visual environmental information for a user. The parameter display module adopts a high-definition screen, has the characteristics of high resolution, high brightness and high contrast, and can clearly display information in various environments. Meanwhile, the parameter display module has the advantages of energy conservation, environmental protection and durability, and can continuously work for a long time to meet various requirements.
In some embodiments of the present application, the mode input module is an important part of the interaction subsystem, mainly for receiving mode input of the user. The intelligent input system based on the artificial intelligence technology can receive input of a user, such as mode selection, parameter setting and the like, through a touch screen, voice recognition and the like, and convert the input into instructions which can be understood and executed by the intelligent station. The mode input module adopts advanced touch screen technology, and can realize accurate and sensitive operation. Meanwhile, the mode input module also adopts an advanced voice recognition technology, so that voice instructions of a user can be accurately recognized and understood, and convenient, quick and natural interaction experience is provided for the user.
In some embodiments of the present application, the human-machine interaction module is another important part of the interaction subsystem, mainly for interaction with the user. The intelligent interaction system based on the artificial intelligence and the Internet of things technology can interact with a user through a graphical interface, a touch screen, voice recognition, body action recognition and other modes, such as information display, input receiving, instruction executing, result feedback and the like. The man-machine interaction module adopts an advanced graphical interface technology, can provide rich, visual and easy-to-use interfaces, and provides pleasant interaction experience for users. Meanwhile, the man-machine interaction module also adopts advanced voice recognition and body action recognition technology, and can realize a natural, friendly and flexible interaction mode.
It is easy to understand that the interaction subsystem of some embodiments of the present application provides a convenient, intuitive and natural interaction experience for a user through the parameter display module, the mode input module and the man-machine interaction module. Each module adopts advanced technology such as Internet of things, artificial intelligence, touch screen, voice recognition, body action recognition and the like, and ensures the accuracy, timeliness and friendliness of interaction. Meanwhile, the modules have the advantages of energy conservation, environmental protection and durability, and can continuously work for a long time in various environments to meet various requirements.
As shown in fig. 8, the display subsystem 150 of some embodiments of the present application includes: a large screen display module 151, an advertisement delivery module 152, a laser projection module 153, and an advertisement display module 154.
The display subsystem is used for displaying various information. The large-screen display module is mainly used for displaying information such as environmental parameters, time, weather and the like, and the advertisement putting module is mainly used for playing advertisements; the large-screen display module is provided with an ambient illuminance sensing device, so that the ambient illuminance can be monitored in real time, and the brightness of the large screen can be dynamically adjusted according to the ambient illuminance. When the ambient brightness is high, the large screen is set in a high-brightness display mode, so that a viewer can clearly see display information; when the ambient brightness is low, the large screen is set in a low brightness display mode, so that a viewer with over-high brightness is prevented from feeling dazzling, the dry look is more comfortable, and the system energy consumption is reduced. The display brightness of the large screen can be dynamically adjusted according to the ambient brightness, so that the energy consumption is reduced as much as possible while the watching effect is ensured. Such dynamic adjustment has not only guaranteed the display effect of large-scale screen, and is that the viewer is more comfortable, can also reduce the energy consumption, can also increase the holistic demonstration life of large-scale screen simultaneously, reduces the holistic operation cost of system. The advertisement screen is usually in low-power consumption low-brightness silence mode, this advertisement delivery module is provided with personnel detection camera, when the camera detects that there is personnel in the advertisement screen 10 meters, further detect whether personnel are watching the advertisement screen, if personnel are not watching the advertisement screen, play the mild music that eases and attract past personnel to pay attention to, if detect that there is personnel are watching the advertisement screen, further analyze personnel's class, play the advertisement that is fit for this class of personnel, advertisement and personnel are generally according to the priority from high to low fall into following several categories: the advertisement screen has the advantages that the advertisement screen can reduce energy consumption when no people exist, prolong the service life of the advertisement screen and improve the effective arrival rate of the advertisement if the advertisement screen detects that a plurality of people exist in the watching personnel, such as young women, middle-aged women, young men, middle-aged men, business people, old people and children; the laser projection module is mainly used for projection display, and a Sielder detection device is used for detecting whether a viewer exists in a room or not in the projection, and the playing is stopped when the viewer does not exist, so that energy sources are saved, and the effective service life of the projector is prolonged; the notice display module is mainly used for displaying site notices, and the notices can be played after being audited by a manager through an auditing module of the control subsystem, and news time administration and notice information of public media signed in advance can also be played.
The display subsystem is an important component in the intelligent site and mainly comprises a large-screen display module, an advertisement putting module, a laser projection module and an announcement display module and is used for displaying various information. These modules will be described in detail below.
In some embodiments of the present application, the large screen display module is mainly used for displaying information such as environmental parameters, time, weather, and the like. This is an IoT technology based smart display system that can receive and process various environmental parameter data, such as temperature, humidity, air quality, noise, etc., in real-time and display the data in a visual form on a large screen. Meanwhile, the large screen display module can also display basic information such as time, date, weather and the like, and provides convenient living references for users. The large screen display module adopts a high definition screen, has the characteristics of high resolution, high brightness and high contrast, and can clearly display information in various environments. In addition, the large-screen display module has the advantages of energy conservation, environmental protection and durability, and can continuously work for a long time to meet various requirements.
In some embodiments of the present application, the advertisement delivery module is primarily used to play advertisements. The intelligent advertisement delivery system based on the artificial intelligence technology can monitor and analyze the crowd watching the advertisement in real time, and automatically select and play the proper advertisement according to the characteristics of the crowd, such as gender, age, occupation and the like, so that the effective arrival rate of the advertisement is improved. The advertisement putting module adopts advanced face recognition and behavior analysis technology, and can accurately identify and analyze the crowd watching the advertisement. In addition, the advertisement delivery module can automatically adjust the playing mode and the content of the advertisement according to environmental conditions such as time, place, people flow and the like so as to achieve the optimal advertisement effect. The advertisement putting module also has the advantages of energy saving, environmental protection and durability, and can automatically enter a low-power consumption, low-brightness and mute mode when no person exists, so that the energy consumption is reduced, and the service life of the advertisement screen is prolonged.
In some embodiments of the present application, the laser projection module is primarily used for projection displays. The intelligent projection system based on the laser technology can clearly project and display various information such as pictures, videos, texts and the like on various surfaces. The laser projection module adopts a laser projector with high resolution, high brightness and high contrast, and can clearly project display information in various environments. Meanwhile, the laser projection module has the advantages of energy conservation, environmental protection and durability, and can continuously work for a long time to meet various requirements. In addition, the laser projection module is also provided with a Style personnel detection device, so that the crowd watching projection can be monitored and analyzed in real time, and the projection can be automatically turned on or off according to the existence of the crowd, so that energy is saved, and the service life of the projector is prolonged.
In some embodiments of the present application, the advertisement display module is mainly used for displaying site advertisements. The intelligent bulletin system based on the internet technology can receive and process various bulletin information such as site bulletin, news time administration, bulletin information and the like in real time, and display the information on a bulletin board in a visual form. The bulletin display module adopts a high-definition screen, has the characteristics of high resolution, high brightness and high contrast, and can clearly display information in various environments. Meanwhile, the bulletin display module has the advantages of energy conservation, environmental protection and durability, and can continuously work for a long time to meet various requirements. The bulletin can be played after being audited by a manager through an audit module of the control subsystem, and news time administration and bulletin information of public media signed in advance can also be played, so that the information can be updated and spread in real time.
In some embodiments of the present application, the large screen display module, the advertisement delivery module, the laser projection module, and the advertisement display module together form a display subsystem that provides rich, real-time, visual information to the user. Each module adopts advanced technology such as IoT, artificial intelligence, laser, internet, etc., which ensures the accuracy, timeliness and validity of the information. Meanwhile, the modules have the advantages of energy conservation, environmental protection and durability, and can continuously work for a long time in various environments to meet various requirements.
The display subsystem of the embodiment of the application enhances the convenience and practicality of the intelligent site by providing various information for the user. In the future, with the development of technology, the functions of the display subsystem will become more and more powerful, so that the intelligent site is more intelligent and humanized.
As shown in fig. 9, a communication subsystem 190 of some embodiments of the present application is used for communication between the subsystems of fig. 2, the communication subsystem comprising: a data transmission module 191, a control signal transmission module 192, a user interface subsystem 193, an operation instruction receiving module 194, an operation state display module 195, and a malfunction alerting module 196.
In the embodiment of the application, the communication subsystem is an information transmitter of the whole intelligent station and is responsible for transmitting the data of the detection subsystem to the control subsystem and transmitting the control signals of the control subsystem to various functional modules.
In some embodiments of the present application, the data transmission module is responsible for transmitting the data of the detection subsystem to the control subsystem by wired or wireless means. The module generally adopts a data transmission protocol, and can ensure the accuracy and the real-time performance of data.
In some embodiments of the present application, the control signal transmission module is responsible for transmitting control signals of the control subsystem to various functional modules in a wired or wireless manner. The module generally adopts a control signal transmission protocol, and can ensure the accuracy and the instantaneity of control signals.
In some embodiments of the present application, the user interface subsystem is a "man-machine interaction device" of the entire smart site, and is responsible for receiving the operation instruction of the user and displaying the working state of the smart site.
In some embodiments of the present application, the operation instruction receiving module is responsible for receiving an operation instruction of a user, such as turning on or off a certain functional module, adjusting an operating parameter of a certain functional module, and so on. The module generally adopts a touch screen or a physical button, and can simply and conveniently receive the operation instruction of a user.
In some embodiments of the present application, the working state display module is responsible for displaying the working state of the smart site, such as the on/off state of various functional modules, the real-time values of various environmental parameters, and so on. The module generally adopts a liquid crystal screen, and can clearly and intuitively display the working state of the intelligent station.
In some embodiments of the present application, the fault alarm module is responsible for sending an alarm signal when the smart site fails, so as to prompt the user to process in time. The module generally adopts a buzzer or an LED lamp, and can immediately and obviously send out an alarm signal.
For example, in some embodiments of the present application, the control subsystem communicates with the detection subsystem, the service providing subsystem, and the power subsystem over a wireless network; the control subsystem communicates with the intelligent equipment of the user through a wireless network to realize remote control and management.
For example, in some embodiments of the present application, the intelligent post system measures irradiance, illuminance, temperature and humidity, and carbon dioxide concentration, respectively, through a photodiode, a photoresistor, a thermistor, and an infrared gas sensor. Environmental information collected by the sensing devices is encoded into digital signals through an encoder and then transmitted to a control subsystem through a data line. The control subsystem uses a microprocessor, generates a corresponding control signal according to a preset control strategy after receiving the environmental information, and then transmits the control signal to the execution module and the man-machine interaction module through a data line. The execution subsystem uses a stepping motor driver, a constant current driver, a solid relay and an electromagnetic valve driver to drive a stepping motor, an LED lamp, refrigeration/heating equipment, an electromagnetic valve and a fan, and changes the environment of a post. The interaction subsystem uses a touch screen to display environment information, receives operation commands of a user, encodes the operation commands into control signals through an encoder, and transmits the control signals to the control subsystem through a data line. After receiving the operation commands of the user, the control subsystem adjusts the control strategy according to the commands to generate new control signals, and the new control signals are transmitted to the execution subsystem through the data line, so that the user can control the post environment.
Example 1: the intelligent post system provided by the embodiment comprehensively utilizes the internet of things technology, the wireless communication technology, the solar technology and the automatic control technology, and forms a brand new post mode integrating environment monitoring, automatic control, multifunctional service and self-sufficient power supply. The post station not only can provide abundant convenience service for users, but also can realize real-time monitoring and regulation of environmental parameters, ensures the comfort level of site environment, simultaneously, realizes self-sufficiency of energy sources through solar power supply, reduces operation cost and is more environment-friendly.
Example 2: on the basis of embodiment 1, the detection subsystem includes an irradiance detection module, an illuminance detection module, a temperature detection module, a humidity detection module, and a carbon dioxide concentration detection module. The modules respectively correspond to five important parameters of irradiance, illuminance, temperature, humidity and carbon dioxide concentration in the environment, and can comprehensively and real-timely monitor the environmental conditions inside and outside the post. The comprehensive environmental monitoring can reflect the working state of the post in real time and can provide accurate data support for the subsequent control subsystem.
Example 3: based on embodiment 2, the irradiance detection module, the illuminance detection module, the temperature detection module, the humidity detection module, and the carbon dioxide concentration detection module have high detection accuracy and stable operation performance. The irradiance detection module can accurately monitor the radiation intensity of the sun and provide data reference for the work of the solar photovoltaic module; the irradiance detection module is not only configured to detect irradiance of the rooftop solar photovoltaic module, but also to detect independent irradiance of each window, so that irradiance information of each window can provide a more accurate control basis for controlling indoor temperature. For example: when the indoor temperature exceeds the set target temperature, searching a window with highest current irradiance according to irradiance data, increasing the shielding degree of the window, and reducing the irradiation entering the room through the window, thereby achieving the aim of cooling; when the indoor temperature is lower than the set target temperature, searching a window with highest current irradiance according to irradiance data, reducing the shielding degree of the window, and increasing the irradiation entering the room through the window so as to achieve the purpose of heating; the illuminance detection module and the temperature detection module can monitor the indoor illumination and temperature conditions of the post, and provide basis for the work of the shading heat insulation module and the temperature control module; the humidity detection module and the carbon dioxide concentration detection module can monitor indoor humidity and carbon dioxide concentration of the post, and data support is provided for the work of the humidity control module and the air purification module. Irradiance data can also play a role in indoor illuminance control. When the indoor illumination is too low, but the temperature does not need to be adjusted, the window with low irradiance can be preferentially selected according to irradiance data of each window, and the transmittance is increased, so that the purpose that the indoor zero degree is increased, but the temperature is unchanged or only rarely changed is achieved. The coordination of the parameters is adopted, and the final purpose is to preferentially use the mode with the minimum energy consumption, and regulate and control the indoor environment factors through the natural environment, so that the intelligent control target is achieved, and the energy consumption is minimum.
Example 4: based on embodiment 1, the control subsystem includes a shading and heat insulation control module, a lighting module control, a temperature control module, a humidity control module, and an air purification control module, which form an automated environmental control system. The shading and heat insulation control module can automatically adjust the opening and closing degree of the curtain according to the irradiation intensity of the sun and the indoor illumination intensity, so as to achieve shading and heat insulation.
Example 5: based on embodiment 4, the control subsystem may automatically adjust the operations of the light shielding and heat insulation module, the lighting module (not shown in the figure), the cooling/heating module, the humidification/dehumidification module, and the air purification module included in the execution subsystem according to the data of the irradiance detection module, the illuminance detection module, the temperature detection module, the humidity detection module, and the carbon dioxide concentration detection module. If the radiation intensity is too high, the shading and heat insulation module can be automatically started to block excessive sunlight from entering a room; when the illumination intensity is too low, the illumination module can be automatically started to provide enough illumination; when the temperature is too high or too low, the refrigerating/heating module can automatically adjust, so that the indoor temperature is kept suitable; when the humidity is too high or too low, the humidifying/dehumidifying module is automatically started to adjust the indoor humidity; when the concentration of carbon dioxide is too high, the air purification module can be automatically started to purify indoor air.
Example 6: on the basis of embodiment 1, the circulation subsystem comprises an automatic vending module, an express receiving and sending module, a community group purchase module, a clothes recycling module and an unmanned vehicle. The modules provide rich functional services for the post, and the use value of the post is greatly increased. The automatic vending module can provide vending of various commodities such as beverages, snacks and the like, and meets shopping requirements of users; the express receiving and dispatching module can realize automatic receiving and dispatching of express, and solves the problem of express taking and delivering; the community group purchase module can organize group purchase activities of communities, and is convenient for residents to live; the clothes recovery module can recover old clothes and recycle resources; the unmanned vehicle module can automatically deliver commodities, and delivery efficiency is improved.
Example 7: based on embodiment 6, the vending module, the express receiving and sending module, the cell group purchase module, the clothes recycling module and the unmanned vehicle are based on the internet of things technology and the wireless communication technology, and can realize remote control and management. The user can operate the post through intelligent device in any place, has greatly improved the convenience of use of post.
Example 8: on the basis of embodiment 1, the power supply subsystem includes a solar photovoltaic module, a power supply module, an energy storage module, and a charging module (not shown in fig. 6). The solar photovoltaic module can convert sunlight into electric energy, the power supply module can provide the electric energy for the whole intelligent post system, the energy storage module can store redundant electric energy, the electric energy is provided when no sunlight exists, and the charging module can charge the battery.
Example 9: on the basis of embodiment 8, the solar photovoltaic module, the power supply module, the energy storage module and the charging module form a complete solar power supply system. Through the system, the intelligent post can realize self-sufficient power supply, so that energy sources are saved, and the operation cost is reduced.
Example 10: based on embodiment 1, the control subsystem may communicate with the detection subsystem, the service providing subsystem, and the power subsystem via a wireless network, so as to implement centralized control of the entire intelligent post system. The control subsystem can receive the data of the detection subsystem, and adjust the working state of the functional module subsystem according to the data so as to maintain the comfort level of the post environment; meanwhile, the power supply of the post can be adjusted according to the state of the power subsystem, so that the normal operation of the post is ensured.
Example 11: based on embodiment 10, the control subsystem may also communicate with the intelligent device of the user through the wireless network, and receive the operation instruction of the user to the post, so as to implement remote control of the user to the post. In addition, the control subsystem can feed back information such as the working state of the post, environmental data and the like to the user, so that the user can know and use the post more conveniently.
Example 12: on the basis of embodiment 1, the intelligent post system is further provided with a safety protection module (not shown in the figure), which comprises a camera, an alarm, a fireproof device and other equipment, so that the safety condition of the post can be monitored in real time, once the abnormal condition is found, the alarm can be immediately started, and related personnel can be notified at the same time, so that the safety of the post is ensured.
Example 13: based on embodiment 12, the camera can monitor the conditions inside and outside the post, the alarm can give an alarm when abnormal conditions are found, the fireproof device can be started immediately when fire is found, the fire source is eliminated, and the safety of the post is ensured.
Example 14: on the basis of embodiment 1, the intelligent post system is also provided with an information release module, which can release contents such as weather forecast, news briefing, advertisement information and the like at regular time to provide information service for users.
Example 15: based on embodiment 14, the information publishing module may publish information through a large screen, voice broadcast, etc., and the user may choose to view or listen to the information according to his own needs, so as to greatly increase the use value of the post.
Example 16: on the basis of the embodiment, the invention also realizes the optimal regulation and control of the system environment by an intelligent multi-means comprehensive regulation and control method.
The purpose of the regulation is to set diversified sensor/detection modules on the system, and to cooperate with various executors/execution modules, through detection of various environmental factors, the regulation of single factor single regulation means is not needed, the regulation is not needed, the linear direct regulation is also needed, the comprehensive optimized environmental regulation after various factors are combined is needed, and finally the effect of intelligent control is achieved. The intelligent control realizes the minimum energy consumption, the minimum environmental intervention and the optimal regulation and control effect.
For example: when the system detects that the indoor environment temperature of the post is higher than the preset target regulation temperature and exceeds a certain threshold, the comprehensive regulation is automatically started.
In general, the prior art scheme is to start the air conditioner to cool down, which is a linear single regulation. Because the radiation sensing module, the light sensing module, the temperature sensing module and other sensors are arranged, and meanwhile, the light shielding and heat insulation module, the temperature control module and other actuators are also arranged, the detection values of the three sensors can be integrated, and comprehensive regulation and control can be performed. When the difference value of the indoor actually measured temperature detected by the temperature sensing module exceeding the preset target regulation temperature is relatively low (for example, the difference value is about 2-4 degrees), and the environmental irradiation intensity is relatively high, the effect of regulating the room temperature with the lowest energy consumption can be realized by regulating the illuminance entering the room. The specific implementation is to interfere the illuminance entering the room through the shading and heat insulation module. But is the transparency and opening/closing degree of each window reduced for each room? At this time, due to the combination of the light sensing modules, the illumination is provided by the shade of some windows, but the incoming radiation is not necessarily strong, and the sun of some windows is facing at the time, so that the irradiance entering the room can be effectively shielded by changing the transmittance. Therefore, under the condition of comprehensively considering irradiance, indoor illumination brightness and temperature requirements, the transparency of the sunny window is reduced, and meanwhile, the transparency of the non-sunny window is increased, so that the transparency of the sunny window is reduced by simply increasing the voltage of the sunny window capacitor glass under the condition that a high-energy-consumption air conditioner is not used, the light inlet amount and the irradiation amount of the window are reduced, and on the other hand, the transparency of the non-sunny window glass is improved by reducing the voltage of the non-sunny window capacitor glass. The comprehensive regulation and control can reduce indoor temperature due to the fact that irradiance entering the room is reduced, meanwhile, the increase of the light entering quantity of the back yin surface is guaranteed, and the indoor illuminance can be controlled intelligently normally.
It should be noted that, this intelligent control needs to comprehensively evaluate real-time measurement values of irradiance, luminosity, temperature and the like, and determine actions of one or more controllers (actuators). The control subsystem is also pre-stored with various regulation means to realize the regulation range and speed of various environmental factors, if the obtained regulation quantity exceeds the regulation range of a single regulation means according to the calculation of the difference between the real-time test value and the target regulation value, the regulation is carried out by combining multiple regulation means. When the multiple regulation means meet the regulation range, the regulation means with low energy consumption is preferentially selected;
when the indoor environment temperature is detected to be higher than the target regulation temperature at night time, the irradiance is low, the transparency of the window is changed, so that the indoor temperature is reduced, and the air conditioner/fresh air system is possibly required to be started through the temperature control module to ensure a certain temperature.
Example 17:
based on the above embodiments, the system may also perform some optimizations:
and a perception module: each sensing device measures environmental parameters through different physical principles. For example, irradiance modules may be measured by photodiodes, illuminance modules may be measured by photoresistors or photodiodes, temperature sensing modules may be measured by thermistors or thermocouples, humidity sensing modules may be measured by humidity sensing resistors, and carbon dioxide concentration modules may be measured by infrared gas sensors.
And a control subsystem: can be realized by a microprocessor or a microcontroller, such as ARM Cortex-M series, STM32 series, PIC series, etc.
The execution subsystem: the driving of the execution device may be achieved by a motor driver, a solenoid valve driver, a solid state relay, or the like. For example, the shading and heat insulation module can drive a stepping motor through a stepping motor driver, the lighting module can drive an LED lamp through a constant current driver, the refrigerating/heating module can drive refrigerating/heating equipment through a solid relay, the humidifying/dehumidifying module can drive an electromagnetic valve through an electromagnetic valve driver, and the air purifying module can drive a fan through a motor driver.
And an interaction subsystem: the display device can be composed of input devices such as a touch screen or keys, a knob and the like and display devices such as a liquid crystal display screen or an LED display screen and the like. For example, a 4.3 inch TFT touch screen with a resolution of 480x272 may be used, which may clearly display environmental information and facilitate user operation.
The above parameters and implementation manners are merely examples, and may be selected and adjusted according to specific requirements in practical applications.
Example 18:
based on the above embodiments, the system may also perform some optimizations:
the system adopts an outdoor small weather station, an indoor temperature and humidity sensor, an air quality sensor, an indoor illuminance sensor, an indoor radiation sensor, a millimeter wave radar detection system and a multi-actuator, wherein the multi-actuator comprises a fresh air system, a sunshade rain-proof system, a dimming system, an electrochromic glass system, an isenthalpic air supply system, a temperature control system, a humidity control system, a photovoltaic power generation system, an energy storage system and the like, and integrates multiple algorithms to achieve the global optimum of non-inductive automation.
And (3) room state control of the room, namely, determining the current mode state of the room, namely, room state confirmation according to the indoor and outdoor environment conditions, the number and distribution condition of people in the room detected by a plurality of millimeter wave radars, and carrying out modularized parameter setting and control on each system through the room state.
And the isenthalpic air supply system detects outdoor temperature and humidity according to the set enthalpy value, and processes the outdoor fresh air to make the fresh air enthalpy value equal to the indoor enthalpy value.
The outdoor sunshade awning receives the sunlight radiation value of the outdoor weather station, combines an indoor refrigerating or heating mode, judges whether to start the sunshade mode, automatically sets the unfolding length of the awning according to the longitude and latitude of the outdoor weather station and the local time after the sunshade is started, fully collects sunlight while shielding heat, and reduces artificial lighting. And when receiving a raindrop detection signal of the outdoor weather station, starting a rain shielding mode.
And the constant-illuminance dimming system automatically dimmes according to the indoor illuminance sensor and the set illuminance value in a room state and the exponential change of the illuminance change recognizable by human eyes, and the dimming range determines a sunlight influence factor and an artificial illumination influence factor according to the installation position of the illuminance sensor and converts the sunlight influence factor and the artificial illumination influence factor into the illuminance value of a working plane.
Electrochromic glass receives and fuses window glass transmissivity, building facade parameters, outdoor weather station data, room state modes and the like, calculates incident solar illumination intensity, and an integrated touch screen controls manual and automatic mode switching of the glass. The ultra-short focal projection needs to be completely shielded when being started.
The solar photovoltaic panel receives the radiation value of the weather station and tracks the incident direction of sunlight, and the maximum efficiency of the angle is adjusted to generate electric energy.
The energy storage device intelligently stores the generated energy, the energy storage device supplies power to the heating ventilation air conditioner, the fresh air system, the lighting system and various devices by using the electric energy generated by the solar panel, the power utilization mode is adopted during normal power generation, the central control unit predicts the sun and the rain in the sun in a meteorological mode, and when the power generation is insufficient, the peak-eliminating and valley-filling mode can be started, and the power grid is connected at night to store power for the power grid, so that the normal use of all devices in the sun is ensured.
The intelligent fresh air system has three ways for calculating fresh air quantity, wherein the first way is to calculate the fresh air quantity according to the space volume of a room and the ventilation times per hour; and thirdly, calculating the fresh air quantity according to the feedback value and the actual measured value of the air quality sensor, and taking the maximum value of three calculated quantities, namely fully using fresh air on the basis of ensuring the minimum fresh air.
In the several embodiments provided in this application, it should be understood that the disclosed apparatus and method may be implemented in other manners as well. The apparatus embodiments described above are merely illustrative, for example, flow diagrams and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of apparatus, methods and computer program products according to various embodiments of the present application. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.
In addition, the functional modules in the embodiments of the present application may be integrated together to form a single part, or each module may exist alone, or two or more modules may be integrated to form a single part.
The functions, if implemented in the form of software functional modules and sold or used as a stand-alone product, may be stored in a computer-readable storage medium. Based on such understanding, the technical solution of the present application may be embodied essentially or in a part contributing to the prior art or in a part of the technical solution, in the form of a software product stored in a storage medium, including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to perform all or part of the steps of the methods described in the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk, or an optical disk, or other various media capable of storing program codes.
The foregoing is merely exemplary embodiments of the present application and is not intended to limit the scope of the present application, and various modifications and variations may be suggested to one skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application. It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.
The foregoing is merely specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present application, and the changes and substitutions are intended to be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.
It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Claims (10)

1. An intelligent post system, the intelligent post system comprising:
the detection subsystem is configured to monitor environmental parameters in real time to obtain environmental parameter values, and uses diversified sensors to detect various influencing factors of the environment in real time, including irradiance, illuminance, temperature, humidity, carbon dioxide concentration and post personnel flow;
the control subsystem is configured to control the working states of related subsystems included in the intelligent post system according to the environmental parameter values, and the intelligent control of the post system is finally achieved by selecting a regulating method with minimum energy consumption and minimum environmental intervention through comprehensively optimized environmental regulation after combining various influencing factors;
a service providing subsystem configured to provide a plurality of service types; and
and the power subsystem is configured to supply power to the related subsystem included in the intelligent post system.
2. The intelligent post system according to claim 1, wherein,
the detection subsystem further includes:
an irradiance detection module configured to monitor an irradiance intensity of the sun and provide the irradiance intensity to the control subsystem;
The power subsystem further comprises:
a solar photovoltaic module configured to convert solar energy into electrical energy; and
an energy storage module configured to store excess electrical energy when the solar photovoltaic module generates electricity;
the control subsystem is configured to calculate the generated energy of the solar photovoltaic module according to the irradiation intensity;
the power subsystem further comprises: and the power dispatching module is configured to automatically dispatch power according to the power demand, the generated energy and the redundant electric energy of the intelligent post system.
3. The intelligent post system of claim 1, wherein,
the detection subsystem further includes:
the illuminance detection module is configured to monitor the illuminance intensity in the site and transmit the measurement result to the control subsystem in real time; and
a temperature detection module configured to monitor a temperature within a site;
the service providing subsystem further comprises:
the shading and heat insulation module is configured to regulate and control illumination and heat inside and outside the intelligent station so as to block external intense illumination and heat invasion;
the control subsystem further comprises:
and the light shielding and heat insulating module is controlled and configured to automatically adjust the working condition of the light shielding and heat insulating module according to the illumination intensity and the temperature.
4. The intelligent post system of claim 3, wherein the shade and insulation module is shade and insulated using both a shade and an insulation coating, the shade adjusting the shade as needed to block different intensity of illumination, the insulation coating preventing heat transfer by reflecting and absorbing heat, the shade and insulation module control being configured to automatically adjust the shade of the shade and automatically adjust the intensity of radiation entering the room.
5. The intelligent post system of claim 3, wherein,
the detection subsystem further includes:
a humidity detection module configured to monitor humidity within the site;
the control subsystem further comprises:
and the humidity control module is configured to regulate and control the humidity in the station according to the humidity and/or the user demand.
6. The intelligent post system of claim 5, wherein the humidity control module is configured to automatically adjust an operating state of the humidification/dehumidification device based on the humidity and a user setting.
7. The intelligent post system of claim 3, wherein,
the detection subsystem further includes:
A carbon dioxide concentration detection module configured to monitor a carbon dioxide concentration within a site;
the service providing subsystem further comprises:
an air purification module configured to purify air within the smart site;
the control subsystem further comprises:
and the air purification module is controlled and configured to automatically adjust the working condition of the air purification module according to the carbon dioxide concentration, automatically start or close a fresh air system and automatically adjust the purification amount of the air purification module.
8. The intelligent post system of claim 7, wherein the air purification module performs air purification by both physical filtration and chemisorption.
9. The intelligent post system of claim 7, wherein the service providing subsystem further comprises: automatic sell module, express delivery transceiver module, district group purchase module, clothing recovery module and unmanned vehicles.
10. The intelligent post system according to claim 1, wherein,
the control subsystem is communicated with the detection subsystem, the service providing subsystem and the power supply subsystem through a wireless network;
The control subsystem communicates with the intelligent equipment of the user through a wireless network to realize remote control and management.
CN202410190288.7A 2024-02-21 2024-02-21 Intelligent post system Active CN117742427B (en)

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