CN219123985U - Intelligent air-conditioner centralized manager and management system - Google Patents

Abstract

The utility model discloses an intelligent air-break centralized manager and a management system, wherein the intelligent air-break centralized manager comprises a power circuit and an MCU (micro control unit), the MCU is connected with a sensor and used for collecting external environment information, the MCU and each intelligent air-break of a link are connected and communicated through a first communication module and used for controlling the closing or opening of a single-way or multi-way intelligent air-break, and reading corresponding air-break states, including real-time voltage, current and power parameters, and the MCU is connected to the Internet through a second communication module to enable a control module to interact with a mobile phone APP or a computer client side. The utility model controls the link open break in real time through the concentrator so as to ensure life and property safety of people and electricity safety of residents, can remotely control the open break of the corresponding area, and improves the working efficiency of power management personnel and company logistics management personnel.

Description

Intelligent air-conditioner centralized manager and management system

Technical Field

The utility model belongs to the technical field of power electronics, and particularly relates to an intelligent air-borne central manager and a management system.

Background

With the progress and development of technology in modern society, various electronic devices are layered endlessly, and high-power electric equipment is more, and the electronic devices are not only in factories, offices, but also in individual families. According to the first aspect, the high-power electrical equipment comprises a water heater, a refrigerator, a washing machine, an air conditioner and the like, a large amount of electric energy is consumed during working, electric equipment connected to a circuit is more and more, current and power carried by the circuit are larger and larger, under the traditional electricity utilization condition, a user cannot easily find the condition of overload of electricity utilization, the overload condition of the circuit occurs, the circuit is heated under the condition that people cannot find in time, the air is damaged, fire is finally initiated, and casualties and property loss are extremely easy to cause. In the second aspect, whether in a factory, a business hall or a company office place, after work or in the case that holiday personnel are not present and electricity is not needed, if electricity utilization equipment of the place is not turned off in time, the place is powered on immediately, so that some devices always work without personnel use and personnel presence, the situation is dangerous, a circuit is easily damaged and fires, and accidents caused by the fire are immeasurable. In the third aspect, the current power grid environment is not good, so that voltage drop easily occurs in the power consumption peak period, and the user electric equipment is easy to cause that the user electric equipment cannot work normally due to insufficient voltage. In the fourth aspect, due to the interference of power grid surge or the lightning influence in thunderstorm weather, the power grid voltage is extremely easy to be too high, the user electric equipment is down and does not work when the user electric equipment is light, and the electric appliance is burned out when the user electric equipment is heavy due to overvoltage.

Disclosure of Invention

The utility model aims to overcome at least one defect in the prior art and provides an intelligent air-break centralized manager and a management system.

The technical scheme of the utility model is realized as follows: the utility model discloses an intelligent air-vent centralized manager which comprises a power circuit, a control module, a first communication module and a second communication module, wherein the power circuit is used for supplying power to the whole intelligent air-vent centralized manager, the control module is connected with the first communication module and used for communicating with an intelligent air-vent through the first communication module, the control module is used for connecting with a sensor for collecting external environment information through a sensor interface, and the control module is connected with the second communication module and used for communicating with an upper computer through the second communication module.

Further, the second communication module comprises one or more of a 4G communication module, a WiFi communication module, an Ethernet communication module and a Bluetooth communication module, wherein the 4G communication module is used for accessing an internet through an inserted SIM card to realize interaction with an upper computer; the WiFi communication module is used for accessing the Internet through WiFi connected with the networked router to realize interaction with the upper computer; the Ethernet communication module is used for accessing the Internet by inserting a networking network cable so as to realize interaction with the upper computer; the Bluetooth communication module is used for being connected with the Bluetooth of the centralized manager in a pairing mode through the Bluetooth of the mobile phone, and interaction with the upper computer is achieved.

Further, the control module is used for communicating with the intelligent air switch through the first communication module and reading the electricity consumption condition of the intelligent air switch; the first communication module is a 485 communication module.

Further, the control module is used for being connected with the sensor through the IO port and used for reading external environment information acquired by the sensor; the sensor comprises one or more of a temperature and humidity sensor, a combustible gas sensor and a smoke sensor, wherein the temperature and humidity sensor is used for acquiring temperature and humidity information of an external environment and transmitting the temperature and humidity information to the control module; the combustible gas sensor is used for reading whether the external environment has combustible gas information which can cause fire or not and transmitting the combustible gas information to the control module; the smoke sensor is used for reading whether the smoke information of the fire alarm exists in the external environment or not and transmitting the smoke information to the control module.

Further, the intelligent air-opening centralized manager comprises three layers of circuit boards, namely a power board for supplying power to a bottom layer, a core control board for a middle layer and a man-machine interaction board on a top layer, wherein the power board is provided with a power circuit, the core control board is provided with a control module, the man-machine interaction board is provided with a display module and an instruction input module, the power board is connected with the core control board through a first pin, and the power core control board is connected with the man-machine interaction board through a second pin.

Further, the power supply circuit comprises a power supply module, a battery charging circuit and a power failure automatic access circuit, wherein the power supply module is used for converting alternating current commercial power into direct current, the battery charging circuit is used for charging the battery, a first input end of the power failure automatic access circuit is connected with an output end of the power supply module, a second input end of the power failure automatic access circuit is connected with an anode of the battery, an output end of the power failure automatic access circuit is used for outputting direct current voltage to supply power for the concentrator, and the power failure automatic access circuit is used for detecting output voltage of the power supply module and controlling connection or disconnection between the second input end of the power failure automatic access circuit and the output end of the power failure automatic access circuit according to the output voltage of the power supply module.

Further, the intelligent air-interface centralized manager further comprises a power failure detection circuit, wherein the power failure detection circuit is connected with the first input end of the control module and used for detecting a power failure signal and transmitting the power failure signal to the control module, and the control module is used for receiving power failure information and sending the power failure information to the mobile phone terminal or the PC through the second communication module.

Further, the intelligent air-conditioner centralized manager also comprises a display module and an instruction input module, wherein the display module is connected with the control module and is used for displaying information of the centralized manager, accessed air-conditioner information, collected corresponding air-conditioner power utilization conditions and collected external environment information; the instruction input module is connected with the control module and is used for realizing man-machine interaction.

The utility model discloses an intelligent electricity utilization centralized management system which comprises an upper computer and the intelligent air-opening centralized manager, wherein the intelligent air-opening centralized manager is communicated with a plurality of intelligent air-openings, the intelligent air-opening centralized manager is connected with a sensor for collecting external environment information, and the intelligent air-opening centralized manager is communicated with the upper computer.

Further, the intelligent air-vent centralized manager is connected to the Internet through the second communication module, so that the control module interacts with the mobile phone APP or the computer client, and the control module of the intelligent air-vent centralized manager is in connection communication with each intelligent air-vent of the link through the first communication module, is used for controlling the closing or opening of the single-channel or multi-channel intelligent air-vent, reads each corresponding air-vent state, comprises real-time voltage, current and power parameters, and monitors and alarms in real time for monitoring the power consumption of equipment under each channel of air-vent.

The utility model has at least the following beneficial effects: the centralized manager is connected to the Internet through one or two of a 4G module, an Ethernet, a WIFI module and the like, a mobile phone APP or a computer is used for making a webpage client to interact with a central processor MCU through instructions, the central processor MCU is connected and communicated with all intelligent air switches of a link through a 485 protocol mode, issuing control of single-channel or multi-channel air switches is implemented, specific parameters of corresponding air switch states, real-time voltage, current, power and the like can be read, real-time monitoring and alarming are carried out for monitoring power consumption of equipment under all air switches, so as to prevent fire disaster caused by conditions of heavy current, overload overheat and the like. The residential electricity safety is guaranteed, the corresponding area is remotely controlled to be opened and closed in the holiday period and the on-off period, and the working efficiency of power management personnel and company logistics management personnel is improved.

The utility model can preset the electricity consumption time and the electricity consumption quantity, can preset the overvoltage and undervoltage conditions of the commercial power to protect the electric equipment of a user, can collect the electricity consumption condition of a circuit, monitors the conditions of short circuit, heavy current, overload and the like which are easy to cause fire, and timely disposes and cuts off the power supply so as to prevent dangerous occurrence, and can check the electricity consumption information of the circuit, including voltage, current, power and the like, at any time and any place through the background of the mobile phone APP, an upper computer and the like.

The utility model also provides temperature and humidity monitoring, combustible gas monitoring and fire smoke monitoring, full-function equipment is provided for preventing the situation, and users can quickly know electricity consumption conditions (including overvoltage, undervoltage, electric leakage, overload, overpower, on-site combustible gas, smoke caused by burning and the like) of an electricity consumption site in real time through a mobile phone app or a webpage client, and safety electricity consumption scenes are set in advance.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic block diagram of an intelligent air-interface centralized manager provided by an embodiment of the present utility model;

fig. 2 is a circuit diagram of a power circuit of an intelligent air-interface central manager according to an embodiment of the present utility model;

FIG. 3 is a circuit diagram of a voltage detection circuit of an intelligent air-interface central manager according to an embodiment of the present utility model;

fig. 4 is a circuit diagram of a 485 communication module of an intelligent air-interface central manager according to an embodiment of the present utility model;

FIG. 5 is a circuit diagram of each sensor of the intelligent air-interface centralized manager provided by an embodiment of the present utility model;

fig. 6 is a circuit diagram of an alarm, a pin header, etc. on a power panel of the intelligent air-interface central manager provided by an embodiment of the present utility model;

fig. 7 is a circuit diagram of a bluetooth communication module of an intelligent air-interface central manager according to an embodiment of the present utility model;

fig. 8 is a circuit diagram of a 4G communication module of the intelligent air-interface central manager according to an embodiment of the present utility model;

fig. 9 is a circuit diagram of an ethernet communication module of an intelligent air-interface central manager according to an embodiment of the present utility model;

FIG. 10 is a circuit diagram of a portion of an MCU of an intelligent air-interface centralized manager provided by an embodiment of the present utility model;

FIG. 11 is another part of the MCU and an interface circuit diagram of the intelligent air interface centralized manager according to the embodiment of the present utility model;

FIG. 12 is a circuit diagram of the remaining circuits of the core control board of the intelligent air-interface centralized manager provided by the embodiment of the utility model after the MCU is disconnected;

fig. 13 is a circuit diagram of a man-machine interaction board of the intelligent air-opening centralized manager provided by the embodiment of the utility model.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second" may include one or more such features, either explicitly or implicitly; in the description of the present utility model, unless otherwise indicated, the meaning of "a plurality", "a number" or "a plurality" is two or more.

Example 1

Referring to fig. 1 to 13, an embodiment of the utility model provides an intelligent air-conditioner centralized manager, which comprises a power circuit, a control module, a first communication module and a second communication module, wherein the power circuit is used for supplying power to the whole intelligent air-conditioner centralized manager, the control module is connected with the first communication module, the first communication module is used for communicating with an intelligent air conditioner, the control module is used for being connected with a sensor through a sensor interface, the control module is connected with the second communication module, and the second communication module is used for communicating with an upper computer.

Further, the second communication module comprises one or more of a 4G communication module, a WiFi communication module, an Ethernet communication module and a Bluetooth communication module, wherein the 4G communication module is used for accessing an internet through an inserted SIM card to realize interaction with an upper computer; the WiFi communication module is used for accessing the Internet through WiFi connected with the networked router to realize interaction with the upper computer; the Ethernet communication module is used for accessing the Internet by inserting a networking network cable so as to realize interaction with the upper computer; the Bluetooth communication module is used for being connected with the Bluetooth of the centralized manager in a pairing mode through the Bluetooth of the mobile phone, and interaction with the upper computer is achieved.

The control module adopts a central processing unit MCU. The central processing unit MCU is connected with the Bluetooth module through a serial port for communication, and various information detected by the centralized manager is locally acquired through Bluetooth. The central processing unit MCU is connected and communicated with the 4G module through a serial port. The centralized manager accesses the Internet through the 4G module. The central processing unit MCU is connected with the Wifi module through a serial port for communication. The centralized manager accesses the Internet through the Wifi module. The central processing unit MCU is connected and communicated with the Ethernet module through the SPI. The centralized manager accesses the internet through a wired network.

Further, the control module is used for communicating with the intelligent air switch through the first communication module and reading the electricity consumption condition of the intelligent air switch; the first communication module is a 485 communication module. And the central processing unit MCU is communicated with the air switch through ISO485 to obtain the voltage and current information on the air switch detection circuit.

Further, the control module is used for being connected with the sensor through the IO port and used for reading external environment information acquired by the sensor; the sensor comprises one or more of a temperature and humidity sensor, a combustible gas sensor and a smoke sensor, wherein the temperature and humidity sensor is used for acquiring temperature and humidity information of an external environment and transmitting the temperature and humidity information to the control module; the combustible gas sensor is used for reading whether the external environment has combustible gas information which can cause fire or not and transmitting the combustible gas information to the control module; the smoke sensor is used for reading whether the smoke information of the fire alarm exists in the external environment or not and transmitting the smoke information to the control module.

The CPU MCU analyzes the environment temperature and humidity through the information detected by the temperature and humidity sensor and reports the environment temperature and humidity to the platform. The CPU MCU analyzes whether the environment has fire or not through detecting the information detected by the smoke sensor, and reports the fire to the platform. The CPU MCU analyzes whether the environment has a fire disaster or not according to the information detected by the flammable gas sensor, and reports the fire disaster to the platform.

Further, the intelligent air-opening centralized manager comprises three layers of circuit boards, namely a power board for supplying power to a bottom layer, a core control board for a middle layer and a man-machine interaction board on a top layer, wherein the power board is provided with a power circuit, the core control board is provided with a control module, the man-machine interaction board is provided with a display module and an instruction input module, the power board is connected with the core control board through a first pin, and the power core control board is connected with the man-machine interaction board through a second pin.

The power panel is provided with a plurality of connectors communicated with the MCU, and the connectors are electrically connected with the core control panel through pin headers, and simultaneously power is supplied to the core control panel through the pin headers.

And a sensor interface is arranged on the power panel and used for connecting a sensor. The power panel is provided with a first communication module for communication with the intelligent air conditioner.

The power supply circuit comprises a power supply module and a DC-DC module, wherein the power supply module is used for converting 220V alternating current commercial power into 5V direct current, and the DC-DC module is used for converting 5V direct current into 3.3V direct current to supply power to the control module.

The core control board is also provided with an Ethernet communication module, a Bluetooth communication module and a 4G communication module.

And a display screen, a WiFi communication module, a status indicator lamp, a man-machine interaction key and a reserved voice interaction module are arranged on the man-machine interaction board.

As an alternative embodiment, the power supply circuit includes power module, battery charging circuit, outage automatic access circuit, power module is used for changing alternating current commercial power into direct current, battery charging circuit is used for charging for the battery, outage automatic access circuit's first input is connected with power module's output, outage automatic access circuit's second input is connected with the positive pole of battery, outage automatic access circuit's output is used for exporting direct current voltage and supplies power for the concentrator, outage automatic access circuit is used for detecting power module's output voltage to switch on or break off between the second input of outage automatic access circuit and its output according to power module's output voltage control.

The automatic access circuit for power failure comprises an MOS tube, wherein the drain electrode of the MOS tube is an output end of the automatic access circuit for power failure and is used for outputting a standby power supply, the source electrode of the MOS tube is connected with a battery anode BAT, the grid electrode of the MOS tube is respectively connected with the output end of a power supply module and one end of a resistor R36, and the other end of the resistor R36 is grounded. The MOS tube is a P-MOS tube. When the mains supply is powered on, the P-MOS tube is in an off state, the power module charges the battery through the battery charging circuit, and when the mains supply is powered off, the P-MOS tube is conducted.

The input end of the DC-DC module is respectively connected with the cathode of the diode D2 and the cathode of the diode D5, the anode of the diode D2 is connected with the output end of the power supply module, and the anode of the diode D5 is connected with the output end of the automatic power-off access circuit, namely the drain electrode of the MOS tube. The input end of the DC-DC module is connected with the positive electrode of the capacitor EC1 and one end of the capacitor C2, and the negative electrode of the capacitor EC1 and the other end of the capacitor C2 are grounded.

The concentrator also comprises a power failure detection circuit, wherein the power failure detection circuit is connected with the first input end of the control module and used for detecting a power failure signal and transmitting the power failure signal to the control module, and the control module is used for receiving power failure information and sending the power failure information to the mobile phone terminal or the PC through the second communication module. When the commercial power is in a power failure, the standby lithium battery can be continuously used for 24 hours by the concentrator, and the power failure information is notified to a user through the short message or the APP client through the 4G module.

Further, the power failure detection circuit comprises a triode Q1, an emitter of the triode Q1 is grounded, a collector of the triode Q1 is connected with a first input end of a control Module (MCU), a base of the triode Q1 is respectively connected with one end of a resistor R1 and one end of a resistor R34, and the other end of the resistor R1 is connected with an output end of a power supply module. The other end of resistor R34 is grounded.

Further, the intelligent air-break centralized manager also comprises a voltage detection circuit for detecting the voltage condition of the mains supply, the voltage detection circuit comprises an electric quantity acquisition chip, the input end of the electric quantity acquisition chip is connected with the voltage input of the mains supply, and the output end of the electric quantity acquisition chip is connected with the second input end of the control module through an isolation optocoupler.

Further, the intelligent air-vent centralized manager also comprises a display module, wherein the display module is connected with the control module and is used for displaying the information of the centralized manager, the accessed air-vent information, the collected corresponding air-vent power utilization condition and the collected external environment information.

Further, the intelligent air-opening centralized manager further comprises an instruction input module, wherein the instruction input module is connected with the control module and used for achieving man-machine interaction.

The display module adopts an LCD display screen, can display concentrator information and connected air-break information, and collects corresponding air-break electricity consumption conditions.

The instruction input module adopts a control key, and the control key enables a user to perform man-machine interaction with the concentrator through the control key, so that some information which the user wants to know is obtained.

Of course, instead of using an LCD display and operating keys, a touch screen may also be used.

The intelligent air-interface centralized manager of the present utility model may also include an alarm circuit.

The intelligent air-interface centralized manager of the present utility model may also include a voice module.

The intelligent air-interface centralized manager of the present utility model may also include a status indication circuit.

The centralized manager comprises an anti-surge circuit, and when the commercial power has surge voltage interference, the piezoresistor can absorb high-voltage power to protect the safety of a later-stage circuit.

The centralized manager can be directly buckled on the guide rail of the power distribution cabinet by using a standard idle guide rail installation mode.

One specific embodiment is: the centralized manager is formed by overlapping and combining three circuit boards. Specifically, be equipped with 220V alternating current mains supply to 5V direct current's power module and 5V to 3.3V on the circuit board and turn to the DC-DC module of MCU system power supply and with intelligent idle open communication's 485 communication module and can external sensor interface such as combustible gas sensor, smoke transducer, the power strip has designed lithium cell emergency power supply circuit simultaneously, can detect the detection circuit etc. of mains voltage condition. The power panel is provided with a plurality of connectors which are communicated with the MCU, the connectors are electrically connected with the core control panel through pins, the core control panel is provided with a central processing unit (MCU) which uses an legal semiconductor STM32F429IGT6 chip, an Ethernet communication module, a Bluetooth module, a 4G communication module, an external watchdog circuit and the like, and the connectors are electrically connected with the human-computer interaction panel through pins, so that communication and power supply are realized. The man-machine interaction board is provided with an LCD display screen, a WiFi communication module, system status indicator lamps, man-machine interaction keys and a reserved voice interaction module.

In this circuit, the STM32F429IGT6 chip plays a central role, and connects several other modules for processing information between the modules. The concrete introduction is as follows:

referring to fig. 2 to 6, the isolated 485 communication module includes an ISO3082 chip and an isolated power supply B0505S, wherein pins 3, 4, 5 and 6 of the ISO3082 chip are electrically connected with pins 120, 121 and 122 of the STM32F429IGT6 chip, respectively. The common 485 communication module comprises 1/2/3/4 pins of the MAX485 chip which are respectively electrically connected with 168/169/170 pins of the STM32F429IGT6 chip. The 6 pins and the 7 pins of the electric quantity acquisition chip HLW8110 are respectively electrically connected with the 152 pins and the 157 pins of the STM32F429IGT6 chip through isolation optocouplers. The smoke sensor is electrically connected to pin 117 of the STM32F429IGT6 chip. The combustible gas sensor is electrically connected with the 155 pin of the STM32F429IGT6 chip. The temperature and humidity sensor is electrically connected with the 88 pins of the STM32F429IGT6 chip. The audible and visual alarm is electrically connected with pin 131 of the STM32F429IGT6 chip. One-key fortification is electrically connected with pin 133 of the STM32F429IGT6 chip. In this embodiment, the communication module is connected with the MCU through a serial port function, the sensor is connected with the MCU through a designated IO port, and the MCU realizes functions through programming analysis and control related circuits.

Referring to fig. 7 to 12, the core control board is provided with an STM32F429IGT6 chip, a W5500 chip, a 24C08 chip, a communication 4G module, and a bluetooth communication module, wherein, pins 32-36 of the W5500 chip are electrically connected with pins 24-27 of the STM32F429IGT6 chip, pins 5 and 6 of the 24C08 chip are electrically connected with pins 129 and 130 of the STM32F429IGT6 chip, pins 6 and 7 of the communication 4G module are electrically connected with pins 42 and 47 of the STM32F429IGT6 chip, and pins 3 and 4 of the bluetooth communication module are electrically connected with pins 68 and 69 of the STM32F429IGT6 chip.

Referring to fig. 13, a man-machine interaction board is provided with an LCD display screen, a WiFi communication module, a voice module, a status indicator light and an interaction button, wherein pins 7/9/10/11 of the LCD display screen are respectively electrically connected with pins 4/5/7/11/12 of an STM32F429IGT6 chip, pins 3 and 4 of the voice module are respectively electrically connected with pins 141 and 144 of the STM32F429IGT6 chip, the status indicator light is respectively electrically connected with pin 50/173/174/175 of the STM32F429IGT6 chip, and the interaction button is respectively electrically connected with pin 43/44/45/54/55/56/57/110 of the STM32F429IGT6 chip.

Example two

The embodiment of the utility model discloses an intelligent electricity consumption centralized management system, which comprises an upper computer and an intelligent air-vent centralized manager as in the embodiment I, wherein the intelligent air-vent centralized manager is communicated with a plurality of intelligent air-vents and is used for reading electricity consumption conditions of the intelligent air-vents, the intelligent air-vent centralized manager is connected with a sensor and is used for collecting external environment information, and the intelligent air-vent centralized manager is communicated with the upper computer and is used for transmitting the read intelligent air-vent electric parameters and the external environment information collected by the sensor to the upper computer.

Further, the intelligent air-vent centralized manager is connected to the Internet through the second communication module, so that the control module interacts with the mobile phone APP or the computer client, and the control module of the intelligent air-vent centralized manager is in connection communication with each intelligent air-vent of the link through the first communication module, is used for controlling the closing or opening of the single-channel or multi-channel intelligent air-vent, reads each corresponding air-vent state, comprises real-time voltage, current and power parameters, and monitors and alarms in real time for monitoring the power consumption of equipment under each channel of air-vent.

The centralized manager can access intelligent space openings of all links through connection of the mobile phone APP or the webpage client, and the conditions of electricity consumption, current, voltage, power consumption and the like of all space openings are read through the centralized manager; the environment temperature and humidity of the installation site can be read in real time through the centralized manager, and whether combustible gas and smoke generated by burnt fires exist on the site or not is alarmed through a platform or an onboard buzzer. The centralized manager comprises an emergency power supply lithium battery, when the commercial power is cut off, the standby lithium battery can be used for the centralized manager to continue to use for 24 hours, and the power cut information is notified to a user through the short message or the APP client through the 4G module.

The intelligent air-conditioner centralized manager can be used for various power utilization occasions such as banks, schools, factories, business halls, families and the like, solves the safety problem of power utilization of the public, presets power consumption, remotely controls various rear concerns such as power utilization, and the like.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (10)

1. An intelligent air-open centralized manager, which is characterized in that: the intelligent air-conditioner comprises a power supply circuit, a control module, a first communication module and a second communication module, wherein the power supply circuit is used for supplying power to the whole intelligent air-conditioner central manager, the control module is connected with the first communication module and is used for communicating with the intelligent air-conditioner through the first communication module, the control module is used for being connected with a sensor for collecting external environment information through a sensor interface, and the control module is connected with the second communication module and is used for communicating with an upper computer through the second communication module.

2. The intelligent air interface central manager according to claim 1, wherein: the second communication module comprises one or more of a 4G communication module, a WiFi communication module, an Ethernet communication module and a Bluetooth communication module, wherein the 4G communication module is used for accessing an internet through an inserted SIM card to realize interaction with an upper computer; the WiFi communication module is used for accessing the Internet through WiFi connected with the networked router to realize interaction with the upper computer; the Ethernet communication module is used for accessing the Internet by inserting a networking network cable so as to realize interaction with the upper computer; the Bluetooth communication module is used for being connected with the Bluetooth of the centralized manager in a pairing mode through the Bluetooth of the mobile phone, and interaction with the upper computer is achieved.

3. The intelligent air interface central manager according to claim 1, wherein: the control module is used for communicating with the intelligent air switch through the first communication module; the first communication module is a 485 communication module.

4. The intelligent air interface central manager according to claim 1, wherein: the control module is used for being connected with the sensor through the IO port and reading external environment information acquired by the sensor; the sensor comprises one or more of a temperature and humidity sensor, a combustible gas sensor and a smoke sensor, wherein the temperature and humidity sensor is used for acquiring temperature and humidity information of an external environment and transmitting the temperature and humidity information to the control module; the combustible gas sensor is used for reading whether the external environment has combustible gas information which can cause fire or not and transmitting the combustible gas information to the control module; the smoke sensor is used for reading whether the smoke information of the fire alarm exists in the external environment or not and transmitting the smoke information to the control module.

5. The intelligent air interface central manager according to claim 1, wherein: including three-layer circuit board, be the human-computer interaction board of the core control panel and the top layer of the power strip of bottom power supply, intermediate level respectively, set up power supply circuit on the power strip, set up control module on the core control panel, set up display module and instruction input module on the human-computer interaction board, be connected through first row of needle between power strip and the core control panel, be connected through the second row of needle between power core control panel and the human-computer interaction board.

6. The intelligent air interface central manager according to claim 1, wherein: the power supply circuit comprises a power supply module, a battery charging circuit and a power failure automatic access circuit, wherein the power supply module is used for converting alternating current mains supply into direct current, the battery charging circuit is used for charging the battery, a first input end of the power failure automatic access circuit is connected with an output end of the power supply module, a second input end of the power failure automatic access circuit is connected with an anode of the battery, an output end of the power failure automatic access circuit is used for outputting direct current voltage to supply power for the concentrator, and the power failure automatic access circuit is used for detecting output voltage of the power supply module and controlling connection or disconnection between the second input end of the power failure automatic access circuit and the output end of the power failure automatic access circuit according to the output voltage of the power supply module.

7. The intelligent air interface central manager according to claim 6, wherein: the mobile phone terminal comprises a control module, a power failure detection circuit and a power failure detection circuit, wherein the power failure detection circuit is connected with a first input end of the control module and used for detecting a power failure signal and transmitting the power failure signal to the control module, and the control module is used for receiving power failure information and sending the power failure information to the mobile phone terminal or the PC through a second communication module.

8. The intelligent air interface central manager according to claim 1, wherein: the power supply voltage detection circuit is used for detecting the condition of the mains supply voltage, the power supply voltage detection circuit comprises a power collection chip, the input end of the power collection chip is connected with the mains supply voltage input, and the output end of the power collection chip is connected with the second input end of the control module through an isolation optocoupler.

9. The intelligent air interface central manager according to claim 1, wherein: the system also comprises a display module and an instruction input module, wherein the display module is connected with the control module and is used for displaying information of the centralized manager, accessed idle running information, collected corresponding idle running electricity utilization conditions and collected external environment information; the instruction input module is connected with the control module and is used for realizing man-machine interaction.

10. An intelligent air-borne central management system is characterized in that: the intelligent air-vent centralized manager comprises an upper computer and the intelligent air-vent centralized manager according to any one of claims 1 to 9, wherein the intelligent air-vent centralized manager is communicated with a plurality of intelligent air-vents, the intelligent air-vent centralized manager is connected with a sensor for collecting external environment information, and the intelligent air-vent centralized manager is communicated with the upper computer.

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