WO2019101187A1

WO2019101187A1 - Intelligent power distribution terminal applied to internet of things and electricity monitoring method

Info

Publication number: WO2019101187A1
Application number: PCT/CN2018/117335
Authority: WO
Inventors: 孙文化; 李选正; 刘泽辰
Original assignee: 深圳时空数字科技有限公司
Priority date: 2017-11-24
Filing date: 2018-11-24
Publication date: 2019-05-31
Also published as: CN107769385A

Abstract

An intelligent power distribution terminal applied to Internet of things and an electricity monitoring method. The intelligent power distribution terminal comprises a box body, and a main switch and several sub-switches mounted in the box body. The main switch and the several sub-switches are intelligent switches having a processor, a power metering module, and a switch control module provided therein. The intelligent power distribution terminal further comprises a communication module and a power supply module. The communication module is connected to the main switch and the several sub-switches. The method comprises: configure the intelligent power distribution terminal in the power consumption place; a user configures a data terminal with the related monitoring software, the intelligent power distribution terminal being connected to the data terminal and a server, separately; the user inquires the operation state of an electrical appliance by means of the sever and the intelligent power distribution terminal, and controls the electrical appliance. Together with the server and the data terminal, the intelligent power distribution terminal can be used for learning about the operation of the electrical appliance in real time remotely and controlling the electrical appliance.

Description

Intelligent power distribution terminal and power monitoring method applied to internet of things

Technical field

The invention relates to an Internet of Things terminal sensing and control device, in particular to an intelligent power distribution terminal applied to an Internet of Things, and relates to an electricity monitoring method based on the Internet of Things.

Background technique

With the development of the Internet of Things, there is a lack of access terminals in the electrical infrastructure. At present, network relays are commonly used instead, but network relays can only realize the opening and closing control of the circuit, and cannot upload the basic energy data to the server. It is impossible to conduct current monitoring, electricity consumption statistics, and large-area electricity consumption data analysis.

Summary of the invention

The object of the present invention is to provide an intelligent power distribution terminal applied to the Internet of Things, so that people can know the working condition of the electrical appliance and control the electrical appliance in real time in different places.

In order to achieve the above object, the technical solution adopted by the present invention is as follows:

An intelligent power distribution terminal applied to an Internet of Things, comprising a box, a main switch installed in the box body and a plurality of sub-switches connected in parallel, wherein the main switch and the plurality of sub-switches have a built-in processor and a power metering module And a smart switch of the switch control module, the smart power distribution terminal further comprising a communication module and a power module for supplying direct current to the communication module and each smart switch, the communication module being connected to the main switch and the plurality of sub-switches It is used to receive power consumption information from each switch and upload it to the server, and receive control information from the server to decode and transmit to the corresponding switch.

In the foregoing intelligent power distribution terminal applied to the Internet of Things, preferably, the communication module includes a first processor, a WIFI interface, an Ethernet interface, and a mobile network interface, and the first processor and the WIFI interface respectively The Ethernet interface and the mobile network interface connection are used to adaptively select the communication network to connect to the server to upload the power usage information and receive the control information.

In the above-described intelligent power distribution terminal applied to the Internet of Things, preferably, the communication module further includes a memory connected to the first processor for storing various parameters and logs. Preferably, the mobile network interface comprises a 5G communication module or a NB-IoT (Narrow Band Internet of Things) communication module.

In the above intelligent power distribution terminal applied to the Internet of Things, preferably, the smart switch comprises a switch, a switch control module composed of a motor and a drive module thereof, and a power meter composed of a current sensor, a voltage sensor and a power calculation unit. a module, and a second processor coupled to the power calculation module, the switch control module, and the communication interface.

In the above-mentioned intelligent power distribution terminal applied to the Internet of Things, preferably, the smart switch further includes a fault detecting module, and the fault detecting module is connected to the second processor for using the communication module to the server Upload the fault information of the smart switch.

In the above intelligent power distribution terminal applied to the Internet of Things, preferably, the smart switch further includes a switch detecting module, and the switch detecting module is connected to the second processor for using the communication module to the server Upload status information of the smart switch.

In the above intelligent power distribution terminal applied to the Internet of Things, preferably, the intelligent power distribution terminal further includes a lightning protection device.

A method for monitoring electricity consumption based on the Internet of Things, the method comprising:

Configuring the intelligent power distribution terminal according to any one of the above items, wherein each of the road electrical appliances is respectively connected to a plurality of switch ports of the intelligent power distribution terminal; the intelligent power distribution terminal is connected to the server through the communication module; the smart power distribution The terminal monitors the power consumption information of each independent power circuit, and encodes and uploads the information to the server;

The user configures a data terminal with associated monitoring software, and the data terminal is in communication connection with the server;

The user sends a query instruction to the server through the data terminal to know the working state of the electrical appliance;

The user sends a control command to the server through the data terminal, and the server transmits the command to the communication module of the intelligent power distribution terminal, and the communication module decodes the control command and sends the control command to the corresponding switch or the main switch to perform the relevant opening or closing. The gate operation controls the corresponding appliance.

In the above-mentioned IoT-based power monitoring method, preferably, the data terminal is a mobile phone, a PAD or a computer; and the power usage site is a home, a building, a community, a unit, a warehouse, or a nobody. Watched device.

In the above-described Internet of Things-based power monitoring method, preferably, the power usage information includes power, fault information, and states of respective switches.

Compared with the prior art, the present invention has at least the following beneficial effects:

Since the smart switch with the built-in processor, the power metering module and the switch control module is used as the main switch and the sub-switch, and the communication module and the power module are configured, the power consumption information of the electric appliances connected to the switches can be separately uploaded to the server. And can receive control commands from the server to control the electrical appliances connected to the switches, cooperate with the server and the data terminal to understand the working condition of the electrical appliances and control the electrical appliances in real time.

DRAWINGS

1 is a schematic structural diagram of an intelligent power distribution terminal according to some embodiments;

2 is a circuit block diagram of the smart switch therein;

3 is a circuit block diagram of a communication module therein;

Figure 4 is a schematic diagram of its use.

Detailed ways

The invention will be further described below in conjunction with the drawings and embodiments.

Referring to FIG. 1 , some embodiments of an intelligent power distribution terminal (smart distribution box) applied to an Internet of Things include: a box body, a lightning protection device 1 installed in the box body, a power module 2, a main switch 3, and a plurality of sub-switches 4 and Communication module 6. A plurality of sub-switches 4 are connected in parallel and then connected to the main switch 3. Each sub-switch is a separate module, and all sub-switches 4 are arranged in the box as a switch array 5, and the number of sub-switches 4 can be flexibly configured as needed.

The lightning protection device 1 is used for filtering protection against high voltage or strong current outside the power grid. The power module 2 supplies power for opening and closing operations and communication of all switches (including the main switch 3 and the sub-switch 4). The main switch 3 controls the power of the sub-switch 4, and simultaneously transmits the current, voltage, and power consumption data of the bus to the communication module 6. The sub-switch 4 is used for opening and closing control of the independent line load power supply, and at the same time, the electric power information data such as current, voltage and power consumption of the independent line is transmitted to the communication module 6. The communication module 6 is used to connect to the server, receive control commands, upload power data of each line, and send alarms such as faults, over temperature, over current, and leakage.

The above-mentioned main switch 3 and a plurality of sub-switches 4 are intelligent switches with a built-in processor, a power metering module and a switch control module, and the circuit composition thereof is schematically shown in FIG.

Referring to FIG. 2, such a smart switch includes: a switch (such as a conventional mechanical circuit breaker), a switch control module 45 composed of a motor and its driving module, and a current sensor, a voltage sensor, and a power metering IC (ie, a power calculating unit) The fuel gauge module 43 and the MCU (ie, the first processor) 41 connected to the power calculation module 43, the switch control module 45, and the bus and power supply terminal (ie, communication interface) 44. The MCU 41 establishes a connection with the communication module 6 through the bus. On the one hand, it controls the opening and closing of the forward and reverse rotation of the motor, and on the other hand, drives the power metering chip to process the measurement and uploads to the communication module 6. Among them, the current sensor can use a transformer, a constantan wire, etc., and the voltage sensor can use a transformer or a voltage detecting circuit composed of a resistor.

The smart switch also includes a fault detection module 42 that is coupled to the MCU 41 (ie, the first processor) for uploading fault information of the smart switch to the server through the communication module 6.

The smart switch further includes a switch detection module 46, which is connected to the MCU 41 (ie, the first processor) for uploading status information of the smart switch to the server through the communication module 6. The smart switch also includes an LED indicator/LCD screen 47 for displaying the status of the smart switch.

The communication module 6 is connected to the main switch 3 and the plurality of sub-switches 4 via a bus such as RS232 or the like. It is used to receive the power consumption information from each switch and upload it to the server, and the instruction issued by the receiving server sends the control information to the corresponding switch. The power usage information described herein may be information such as current, voltage, power, fault, and switch status. The circuit composition of the communication module is schematically shown in FIG.

Referring to FIG. 3, the communication module 6 includes an MCU (ie, a second processor) 61, a WIFI interface 63, an Ethernet interface 62, and a mobile network interface 66. The second processor is respectively associated with the WIFI interface 63 and the Ethernet interface 62. The mobile network interface 66 is connected to adaptively select a communication network to connect to the server to upload power usage information and receive control information. Mobile network interface 66 may be a mobile communication module of various standards for mobile, communications, and/or telecommunications. It can be seen that the communication module 6 is compatible with a plurality of network modes and can automatically select a switching network.

The communication module 6 is connected to the power supply terminal 64 via its bus and other switches. The communication module 6 also incorporates an RTC clock 68 for providing metering and control of the clock source. The communication module 6 also includes a memory 67 that is coupled to the second processor for storing various parameters and logs. The communication module 6 is also provided with an LED indication 65, which can display the working state of the communication module.

Referring to FIG. 4, some embodiments of the power monitoring method based on the Internet of Things include:

The intelligent power distribution terminal 100 is configured in a power usage place, and each of the power consumers 200 is connected to a plurality of switch 4s of the smart power distribution terminal; the smart power distribution terminal 100 is connected to the server 400 through the communication module 6; The terminal 100 monitors the power consumption information of each independent power circuit, and encodes and uploads the information to the server 400;

The user configures a data terminal 500 with associated monitoring software, and the data terminal 500 is communicatively coupled to the server 400;

The user sends a query instruction to the server 400 through the data terminal 500 to know the working state of the electrical appliance;

The user sends a control command to the server 400 through the data terminal 500, and the server 400 transmits the command to the communication module 6 of the intelligent power distribution terminal 100, and the communication module 6 decodes the control command and sends it to the corresponding switch 4 or the main switch 3. Control the corresponding appliance by performing the relevant opening or closing operation.

In Fig. 4, 300 denotes AC mains, 1 denotes a lightning arrester, and 2 denotes a power supply module.

Among them, the data terminal can use a mobile phone, a PAD or a computer. The power usage site may be a home, a building, a community, a unit, a warehouse, or an unattended device. The power usage information may include power, fault information, and status of each switch.

Some of the above embodiments have at least the following effects:

1. When applied to the home, the intelligent power distribution terminal 100 cooperates with the cloud server 400 and the mobile phone client (ie, the data terminal) to remotely control the power supply of the home lighting and the household appliance. It is also possible to remotely check the household electricity usage to prevent forgetting power or accidents caused by power outages.

2. When applied to the whole rental house, the intelligent power distribution terminal 100 cooperates with the cloud server 400 and the mobile phone client (ie, the data terminal) to remotely check the power consumption of each tenant.

3. It is widely used in the area above the community level. The intelligent power distribution terminal 100 cooperates with the cloud server 400 and the computer client (ie, the data terminal) to implement statistical analysis of the regional power consumption. Functions such as power metering, power factor measurement, and fault alarm can be connected to the cloud through the Internet of Things to provide data sources for smart grid big data.

4. The intelligent power distribution terminal 100 is used as a remote switch of an unattended device such as a communication base station or a photovoltaic power station, and can automatically reclose.

5, can achieve power metering, remote control, fault alarm, time switch and other functions can achieve pre-paid, intelligent maintenance, central control, can be applied to schools, municipalities, residential and other occasions.

The present invention has been described in detail with reference to the preferred embodiments thereof, and the detailed description is not to be construed as limiting the scope of the invention. Various refinements, equivalent transformations, and the like performed by the above-described embodiments under the present invention should be included in the scope of the present invention.

Claims

An intelligent power distribution terminal applied to an Internet of Things, comprising a box body, a main switch (3) installed in the box body, and a plurality of sub-switches (4) connected in parallel, wherein the main switch and the plurality of sub-switches are A smart switch having a built-in processor, a power metering module, and a switch control module, the smart power distribution terminal further includes a communication module (6) and a power module (2) for supplying DC power to the communication module and each smart switch. The communication module is connected to the main switch and the plurality of sub-switches for receiving power consumption information from the respective switches and uploading the control information to the server, and transmitting the control information to the corresponding switch.
The intelligent power distribution terminal applied to the Internet of things according to claim 1, wherein the communication module comprises a first processor, a WIFI interface, an Ethernet interface, and a mobile network interface, wherein the first processor and the first processor respectively The WIFI interface, the Ethernet interface, and the mobile network interface connection are used to adaptively select a communication network to connect to the server to upload power usage information and receive control information.
The intelligent power distribution terminal applied to the Internet of things according to claim 2, wherein the communication module further comprises a memory, and the memory is connected to the first processor for storing various parameters and logs. The mobile network interface includes a 5G communication module or an NB-IoT communication module.
The intelligent power distribution terminal applied to the Internet of things according to claim 1, wherein the intelligent switch comprises a switch, a switch control module (45) composed of a motor and a drive module thereof, and a current sensor, a voltage sensor, and A power metering module (43) composed of a power calculating unit, and a second processor connected to the power calculating module, the switch control module, and the communication interface.
The intelligent power distribution terminal for the Internet of Things according to claim 4, wherein the smart switch further comprises a fault detection module, and the fault detection module is connected to the second processor for The communication module uploads the fault information of the smart switch to the server.
The intelligent power distribution terminal applied to the Internet of things according to claim 4, wherein the smart switch further comprises a switch detecting module, wherein the switch detecting module is connected to the second processor, and configured to pass the The communication module uploads status information of the smart switch to the server.
The intelligent power distribution terminal applied to the Internet of things according to claim 1, wherein: the intelligent power distribution terminal further comprises a lightning protection device.
A method for monitoring electricity consumption based on the Internet of Things, characterized in that the method for monitoring electricity consumption based on the Internet of Things comprises:

The intelligent power distribution terminal (100) according to any one of claims 1 to 7 is configured, wherein each of the road electrical appliances is respectively connected to a plurality of sub-switches of the intelligent power distribution terminal; the intelligent power distribution terminal passes through the communication module thereof The server (400) is connected; the intelligent power distribution terminal monitors the power consumption information of each independent power circuit, and encodes and uploads the information to the server;

The user configures a data terminal (500) with associated monitoring software, and the data terminal is in communication connection with the server;

The user sends a query instruction to the server through the data terminal to know the working state of the electrical appliance;

The user sends a control command to the server through the data terminal, and the server transmits the command to the communication module of the intelligent power distribution terminal, and the communication module decodes the control command and sends the control command to the corresponding switch or the main switch to perform the relevant opening or closing. The gate operation controls the corresponding appliance.
The method for monitoring electricity consumption based on the Internet of things according to claim 8, wherein the data terminal is a mobile phone, a PAD or a computer; and the power usage site is a home, a building, a community, a unit, Warehouse or unattended equipment.
The Internet of Things-based power monitoring method according to claim 8, wherein the power consumption information includes power, fault information, and states of respective switches.