CN109343408B - Strong electricity network intelligent management system - Google Patents

Abstract

The invention provides an intelligent management system of a strong current network, which comprises the strong current network and a background server, wherein the strong current network comprises a plurality of intelligent sockets, a plurality of intelligent air switches and a concentrator connected with the intelligent air switches, and the intelligent sockets and the concentrator are in communication connection with the background server; the intelligent socket comprises a capacitive load, a first on-off control module, a front-end current acquisition module, a main controller and a communication module, wherein the first on-off control module is used for controlling whether the capacitive load is connected into a socket circuit or not, the main controller is electrically connected with the first on-off control module, and the front-end current acquisition module is used for acquiring the total input current of the intelligent socket and transmitting the acquired current parameters to the main controller; the background server is used for acquiring total input current of each intelligent socket before and after the first on-off control module is switched on and off, and analyzing to obtain a line topology structure diagram of the strong current network. The invention can obtain the line topology structure chart of the strong electricity network, and is convenient for managing the strong electricity network.

Description

Strong electricity network intelligent management system

Technical Field

The invention relates to the technical field of strong current networks, in particular to an intelligent management system of a strong current network.

Background

The electric power network generally comprises equipment such as sockets and air switches, and after the construction of the electric power network is finished, the connection relation of each equipment and the states of the equipment and lines are difficult to understand, so that the management is difficult. The line topological graph of the power network can reflect the connection relation of each device and the devices in the network, and with the line topological graph, the distribution and the superior-inferior relation of each device can be conveniently known, more useful information such as line aging, fault alarm and the like can be conveniently mined, and the functions of line monitoring and protection can be further realized.

Current ordinary socket function singleness, only be used for providing power source for the electrical apparatus, along with the improvement of standard of living, people require more and more high to the intelligent degree of electrical apparatus, smart jack should be transported and born, smart jack (SmartPlug) is emerging electric products, be under the thing networking concept, with the product that the concept of intelligent house accompanies the development, now indicate built-in Wifi module usually, the socket of function operation is carried out to the customer end through intelligent terminal, but traditional smart jack only measures the current of socket external output, can't measure the total current of self input, can't go out the topological structure of circuit through smart jack analysis.

Therefore, there is a need to improve the existing smart sockets and design a strong power network intelligent management system capable of obtaining a strong power network circuit topology structure diagram.

Disclosure of Invention

The invention aims to provide an intelligent management system for a high-voltage network, which aims to solve the problems that the connection relation of each device and the states of the devices and lines of the existing high-voltage network are satisfactorily obtained and the management is difficult.

The invention is realized by the following steps:

the invention provides an intelligent management system of a strong electricity network, which comprises the strong electricity network and a background server, wherein the strong electricity network comprises a plurality of intelligent sockets, a plurality of intelligent air switches connected with the intelligent sockets and a concentrator connected with the intelligent air switches, and the intelligent sockets and the concentrator are in communication connection with the background server;

the intelligent socket comprises a capacitive load, a first on-off control module, a front-end current acquisition module, a main controller and a communication module, wherein the first on-off control module is used for controlling whether the capacitive load is connected into a socket circuit or not, the main controller is electrically connected with the first on-off control module and is used for controlling the on-off of the first on-off control module, the front-end current acquisition module is electrically connected with the main controller and is used for acquiring the total input current of the intelligent socket and transmitting the acquired current parameters to the main controller, and the communication module is electrically connected with the main controller and is used for realizing the communication between the main controller and a background server;

the background server is used for controlling the on-off of the first on-off control module of each intelligent socket, and is also used for acquiring the total input current of each intelligent socket before and after the on-off of the first on-off control module, and analyzing the total input current to obtain a circuit topology structure diagram of the strong current network.

Further, the specific method for obtaining the total input current of each intelligent socket before and after the first on-off control module is turned on and off by the background server and analyzing the total input current to obtain the line topology structure diagram of the strong power network is as follows:

s1, sending control signals to the main controller of each socket, and controlling the first on-off control modules of all the sockets to be switched off so as to initialize the current states of all the sockets and the idle switch;

s2, acquiring the total input current values of all sockets and all idle switches through the main controller, and storing the total input current values to a set 1;

s3, sending a control signal to the main controller of the socket A to control the conduction of the first on-off control module of the socket A;

s4, acquiring the total input current values of all sockets and the air switches through the main controller again, and storing the total input current values to a set 2;

s5, comparing the data of set 2 and set 1, and obtaining one or more upper level sockets and upper level air switches of socket A according to the basic principle of the strong electricity network circuit;

s6, circularly executing the steps S1-S5, and starting the first on-off control modules of different sockets in each circle to obtain one or more upper sockets and upper air switches of all the sockets;

and S7, generating a heavy current network socket and an air-open circuit topological structure chart according to the upper and lower level relations of all the sockets and the air-open circuit.

Further, the front-end current acquisition module is a current transformer.

Furthermore, the intelligent socket and the intelligent air switch both comprise a rear-end current acquisition module and a voltage acquisition module, the rear-end current acquisition module is used for acquiring external output current parameters of the intelligent socket or the intelligent air switch, and the voltage acquisition module is used for acquiring external output voltage parameters of the intelligent socket or the intelligent air switch.

Further, the background server is further configured to obtain an external output current parameter and an external output voltage parameter of each smart socket and each smart air switch, analyze an operating state of each smart socket and each smart air switch and whether a line has a fault or is aged according to the electrical parameters, and display an analysis result in a circuit topology diagram.

Furthermore, the intelligent socket also comprises a display module for displaying the electrical parameters in real time, and the display module is electrically connected with the main controller.

Further, the intelligent socket further comprises a second on-off control module for controlling whether the intelligent socket outputs current to the outside.

Further, the first on-off control module and the second on-off control device are both relays.

Further, the background server is also used for analyzing abnormal conditions of all sockets and the air switch and carrying out early warning.

Further, the system also comprises an APP terminal which communicates with the background server through a router.

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

the intelligent management system for the strong current network provided by the invention improves the existing intelligent socket, obtains the total input current of each intelligent socket before and after the first on-off control module is switched on and off by using the server, analyzes the total input current to obtain the line topology structure chart of the strong current network, can conveniently know the distribution and the up-down relation of each device through the line topology structure chart, and conveniently excavates more useful information, such as line aging, fault alarm and the like, thereby realizing the functions of monitoring and protecting the line and conveniently managing the strong current network.

Drawings

FIG. 1 is a block diagram of an intelligent management system for a high power network according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a smart jack provided in an embodiment of the present invention;

fig. 3 is an exemplary diagram of a topology structure of a high voltage network circuit according to an embodiment of the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, an embodiment of the present invention provides an intelligent management system for a strong electric network, including a strong electric network and a background server, where the strong electric network includes a plurality of smart sockets, a plurality of intelligent air switches connected to the smart sockets, and a concentrator connected to the plurality of intelligent air switches, and both the smart sockets and the concentrator are in communication connection with the background server.

As shown in fig. 2, the smart socket includes a housing, a terminal installed on the housing, a capacitive load, a first on-off control module, a front current collection module, a main controller, and a communication module, where the terminal includes a first terminal LI, a second terminal LO, a third terminal N, and a fourth terminal PE, the first terminal LI and the second terminal LO are used for connecting a live wire, the third terminal N is used for connecting a zero wire, the fourth terminal PE is used for connecting a ground wire, the first on-off control module and the capacitive load are sequentially connected in series between the second terminal LO and the third terminal N to form a first loop circuit, the main controller is electrically connected with the first on-off control module and is used for controlling the first on-off control module to control the on-off of the first loop circuit by controlling the on-off of the first on-off control module, therefore, whether the capacitive load is connected into the socket circuit or not can be controlled, the front-end current acquisition module is connected between the first wiring terminal LI and the second wiring terminal LO in series, the front-end current acquisition module is also electrically connected with the main controller and used for acquiring the total input current of the intelligent socket in real time and transmitting the current parameters to the main controller, and the communication module is electrically connected with the main controller and used for realizing communication between the main controller and the background server. The background server is used for controlling the on-off of the first on-off control module of each intelligent socket, and is also used for acquiring the total input current of each intelligent socket before and after the on-off of the first on-off control module, and analyzing the total input current to obtain a circuit topology structure diagram of the strong current network.

In the above embodiment, the main controller is configured to receive a control instruction from the background server, and control on/off of the first on/off control modules of the smart sockets, so as to control on/off of the first loop circuit, that is, whether the capacitive load is connected to the socket circuit is controlled, before and after the capacitive load is connected, a total input current of the smart socket may change, and accordingly, a total input current of a higher-level socket or a higher-level open circuit of the smart socket may also change. The method comprises the steps that the front-end current acquisition module acquires the total input current of each intelligent socket before and after the first on-off control module is turned on and off, the current parameters are transmitted to the background server, a software program which obtains a topological structure diagram through the current parameter analysis is designed in advance in the background server, the background server can analyze the circuit topological structure diagram of the strong current network according to the current parameters, the topological structure diagram is the connection relation between the intelligent sockets and the air switches, and through the topological structure, the situation that the intelligent sockets are connected under each air switch can be obtained, and the air switch is connected under each intelligent socket can be obtained.

Further, the specific method for obtaining the total input current of each intelligent socket before and after the first on-off control module is turned on and off by the background server and analyzing the total input current to obtain the line topology structure diagram of the strong power network is as follows:

and S1, the background server sends control signals to the main controllers of all the sockets to control the first on-off control modules of all the sockets to be switched off, so that the capacitive load is switched off to initialize the current states of all the sockets and the idle switch.

And S2, the background server acquires the total input current values of all the sockets and the air switches through the main controller and stores the total input current values to the set 1.

And S3, the background server sends a control signal to the main controller of the socket A to control the conduction of the first on-off control module of the socket A, the capacitive load is connected into the circuit, and the total input current of the socket is increased.

And S4, the background server acquires the total input current values of all the sockets and the air switches through the main controller again, and stores the total input current values to the set 2.

And S5, comparing the data of the set 2 and the set 1, and acquiring one or more upper sockets and upper air switches of the socket A according to the basic principle of the high-voltage network circuit.

Specifically, if the topology switch of the socket a is turned on, the capacitive load of the socket a is connected to the circuit, the total input current of the socket a increases, and according to the basic principle of the high-voltage network circuit, the total input current of the upper socket or the upper level open of the socket a also increases, so that according to the method, after the topology switch of the socket a is turned on, the total input current of another certain socket or the upper level open of the socket a increases, the socket or the upper level open is the upper socket or the upper level open of the socket a, and one or more upper level sockets and upper level open of the socket a can be determined by the method.

And S6, circularly executing the steps S1-S5, and starting the first on-off control modules of different sockets in each circle to obtain one or more upper sockets and upper air switches of all the sockets.

S7, generating a topology structure diagram of the high voltage network socket and the open circuit according to the relationship between the upper and lower levels of all the sockets and the open circuit, as shown in fig. 3.

Specifically, the obtained superior sockets and superior air switches of all the sockets can obtain a circuit topology diagram of the whole strong power network socket and the air switches, and the generated circuit topology diagram can be displayed through a display screen.

According to the method for generating the line topology of the strong electricity network, the topological switches of the sockets are sequentially turned on, the superior sockets and the superior switches of the sockets are obtained, and then the line topological graphs of all the sockets and the empty switches in the strong electricity network are generated, so that the automatic generation of the line topological graphs can be realized, and the method is simple and reliable.

In the circuit of the smart jack, the front-end current collection module is preferably a current transformer.

As a preferred option of this embodiment, the smart socket and the intelligent air switch both include a rear-end current collection module and a voltage collection module, the rear-end current collection module is used for collecting external output current parameters of the smart socket or the intelligent air switch, and the voltage collection module is used for collecting external output voltage parameters of the smart socket or the intelligent air switch. The background server is further used for acquiring external output current parameters and external output voltage parameters of each intelligent socket and each intelligent air switch, analyzing the running states of the intelligent sockets and the intelligent air switches and whether the line has faults or ageing according to the electrical parameters, and displaying the analysis result in a line topology diagram.

The specific implementation modes of the rear-end current acquisition module and the voltage acquisition module are described below by taking an intelligent socket as an example, the intelligent socket further comprises the rear-end current acquisition module, the rear-end current acquisition module is connected in series on the second wiring terminal LO or the third wiring terminal N, and the rear-end current acquisition module is further electrically connected with the main controller and used for acquiring current parameters on the second wiring terminal LO or the third wiring terminal N, namely, externally outputting the current parameters and transmitting the current parameters to the main controller. Preferably, the voltage acquisition module is connected in series between the second terminal LO and the third terminal N, and is electrically connected with the main controller, and is used for acquiring external output voltage parameters and transmitting the acquired voltage parameters to the main controller.

Preferably, the smart jack further comprises a display module for displaying the electrical parameters in real time, the display module is arranged on the shell of the smart jack, and the display module is electrically connected with the main controller.

In the above embodiment, the main controller of the smart jack can display the electric parameters collected by the front-end current collection module, the rear-end current collection module and the voltage collection module on the display module in real time, and in addition, the main controller can also transmit the electric parameters to the background server, and the background server can analyze whether the circuit of the smart jack has a circuit fault or is aged or not through the electric parameters, and display the circuit condition of the smart jack on the display module, for example, display the circuit of the smart jack to be normal or have the circuit fault and the like on the display module.

Preferably, the smart socket further comprises a second on-off control device, the second on-off control device is connected in series to the second terminal LO or the third terminal N, and the second on-off control device is further electrically connected to the main controller; and the main controller is used for controlling the on-off of the second on-off control device, so that the on-off of the circuit of the second wiring terminal LO or the third wiring terminal N is controlled.

In the above embodiment, the background server may send a control signal to the main controller as needed, so as to control the connection or disconnection of the second connection control module, and the second connection control module is connected in series to the second terminal LO or the third terminal N and is used for controlling whether the smart socket outputs current to the outside, so that the connection or disconnection of the second connection control module will cause the connection or disconnection of the whole smart socket, and a remote switching-off/switching-on function is realized.

Preferably, the first on-off control module and the second on-off control device are both relays. In the above embodiment, the relay is a commonly used intelligent switch assembly in the prior art, and the main controller can control the attraction and the flicking of the relay, so that the connection or the disconnection of the corresponding line is realized.

Preferably, an anti-surge device is connected in series in the first loop circuit. In the above embodiment, due to the existence of the capacitive load, a large surge current may be generated at the moment of circuit opening, and the surge current may directly cause the contacts of the relay to be bonded due to an excessive current and thus cannot be bounced open.

Preferably, the main controller is an MCU microprocessor. Preferably, the smart socket further comprises an alarm module, and the alarm module is electrically connected with the main controller.

In the above embodiment, the background server determines whether the smart socket or the smart idle open circuit is abnormal, including leakage, open circuit, power abnormality, voltage abnormality, current abnormality, and the like, according to the received electrical parameter, and if the smart socket or the smart idle open circuit is abnormal, controls the alarm module to send an alarm signal.

The system also comprises an APP terminal which is communicated with the background server through a router. APP terminal and backend server wireless connection, the APP terminal can visit backend server through the password to can look over the topological structure of system, if certain sky open control that several smart jack, every sky open and smart jack's running state, can control smart jack's break-make simultaneously, for example, need certain smart jack disconnection, only need select corresponding smart jack, click disconnection smart jack, backend server sends control signal to main control unit promptly, main control unit control second break-make control module disconnection, thereby realize the disconnection that corresponds smart jack.

The above embodiment is that the intelligent air switch can also be designed as a line structure of the smart socket, and the topology of the line can also be obtained through the intelligent air switch.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (9)

1. The utility model provides a forceful electric power network intelligent management system which characterized in that: the intelligent air switch system comprises an electric power network and a background server, wherein the electric power network comprises a plurality of intelligent sockets, a plurality of intelligent air switches connected with the intelligent sockets and a concentrator connected with the intelligent air switches, and the intelligent sockets and the concentrator are in communication connection with the background server;

the intelligent socket comprises a capacitive load, a first on-off control module, a front-end current acquisition module, a main controller and a communication module, wherein the first on-off control module is used for controlling whether the capacitive load is connected into a socket circuit or not, the main controller is electrically connected with the first on-off control module and is used for controlling the on-off of the first on-off control module, the front-end current acquisition module is electrically connected with the main controller and is used for acquiring the total input current of the intelligent socket and transmitting the acquired current parameters to the main controller, and the communication module is electrically connected with the main controller and is used for realizing the communication between the main controller and a background server;

the background server is used for controlling the on-off of the first on-off control module of each intelligent socket, acquiring the total input current of each intelligent socket before and after the on-off of the first on-off control module, and analyzing to obtain a circuit topology structure diagram of the strong current network;

the specific method for obtaining the total input current of each intelligent socket before and after the first on-off control module is switched on and off by the background server and obtaining the line topology structure diagram of the strong power network by analysis is as follows:

s1, sending control signals to the main controller of each socket, and controlling the first on-off control modules of all the sockets to be switched off so as to initialize the current states of all the sockets and the idle switch;

s2, acquiring the total input current values of all sockets and all idle switches through the main controller, and storing the total input current values to a set 1;

s3, sending a control signal to the main controller of the socket A to control the conduction of the first on-off control module of the socket A;

s4, acquiring the total input current values of all sockets and the air switches through the main controller again, and storing the total input current values to a set 2;

s5, comparing the data of set 2 and set 1, and obtaining one or more upper level sockets and upper level air switches of socket A according to the basic principle of the strong electricity network circuit;

s6, circularly executing the steps S1-S5, and starting the first on-off control modules of different sockets in each circle to obtain one or more upper sockets and upper air switches of all the sockets;

and S7, generating a heavy current network socket and an air-open circuit topological structure chart according to the upper and lower level relations of all the sockets and the air-open circuit.

2. The intelligent management system for strong electric network as claimed in claim 1, wherein: the front-end current acquisition module is a current transformer.

3. The intelligent management system for strong electric network as claimed in claim 1, wherein: the intelligent socket with the empty division of intelligence all includes rear end current acquisition module and voltage acquisition module, rear end current acquisition module is used for gathering the external output current parameter of intelligent socket or the empty division of intelligence, voltage acquisition module is used for gathering the external output voltage parameter of intelligent socket or the empty division of intelligence.

4. The intelligent management system for strong electric network as claimed in claim 3, wherein: the background server is further used for acquiring external output current parameters and external output voltage parameters of each intelligent socket and each intelligent air switch, analyzing the running states of the intelligent sockets and the intelligent air switches and whether the line has faults or ageing according to the electrical parameters, and displaying the analysis result in a line topology diagram.

5. The intelligent management system for strong electric network as claimed in claim 1, wherein: the intelligent socket further comprises a display module for displaying the electrical parameters in real time, and the display module is electrically connected with the main controller.

6. The intelligent management system for strong electric network as claimed in claim 1, wherein: the intelligent socket further comprises a second on-off control module used for controlling whether the intelligent socket outputs current outwards or not.

7. The intelligent management system for strong electric network of claim 6, wherein: the first on-off control module and the second on-off control device are both relays.

8. The intelligent management system for strong electric network as claimed in claim 1, wherein: the background server is also used for analyzing abnormal conditions of all sockets and the air switch and carrying out early warning.

9. The intelligent management system for strong electric network as claimed in claim 1, wherein: the system also comprises an APP terminal which is communicated with the background server through a router.

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