CN219437011U - Multi-communication protocol debugging equipment - Google Patents

Abstract

The application discloses a multi-communication protocol debugging device, which comprises a detection board, a control board, an interface board, an adapter, a switch and a communication manager; the detection board and the interface board are connected with the control board through data lines, the detection board and the control board are connected with the adapter through a communication interface, and the adapter, the switch and the communication manager are connected through network cables; the switch is configured to communicate with an energy management system via a first communication protocol and the communication manager is configured to communicate with the energy management system or a coordinator controller via a second communication protocol. According to the method and the device, desktop debugging of communication protocols such as Modbus TCP, IEC18650MMS, IEC18650GOOSE and IEC104 between PCS and EMS and between the coordination controllers is realized, the field debugging time is saved, and the field debugging progress is accelerated.

Description

Multi-communication protocol debugging equipment

Technical Field

The application relates to the technical field of energy storage, in particular to a multi-communication protocol debugging device.

Background

An energy storage converter (PCS) in the energy storage system is communicated with an Energy Management System (EMS) through communication protocols such as Modbus TCP, IEC61850 MMS and IEC104, and is communicated with a coordination controller through communication protocols such as Modbus TCP and IEC61850 GOOSE. In the field system debugging process, various problems such as a communication point table, hardware, wiring, interference and the like are coupled together, so that analysis is difficult, time and labor are wasted, and the field system debugging progress is influenced.

Disclosure of Invention

The application aims at providing a multi-communication protocol debugging device so as to realize desktop debugging of communication protocols such as Modbus TCP, IEC18650MMS, IEC18650GOOSE, IEC104 and the like between PCS and EMS and between a coordination controller, save field debugging time and accelerate field debugging progress.

In one aspect, the present application provides a multi-communication protocol debugging device, where the multi-communication protocol debugging device includes a detection board, a control board, an interface board, an adapter, a switch, and a communication manager;

the detection board and the interface board are connected with the control board through data lines, the detection board and the control board are connected with the adapter through a communication interface, and the adapter, the switch and the communication manager are connected through network cables;

the switch is configured to communicate with an energy management system via a first communication protocol and the communication manager is configured to communicate with the energy management system or a coordinator controller via a second communication protocol.

In another aspect, the present application provides a multi-communication protocol debugging device, where the multi-communication protocol debugging device includes a first detection board, a first control board, a first interface board, a first adapter, a second detection board, a second control board, a second interface board, a second adapter, a switch, and a communication manager;

the first detection board and the first interface board are connected with the first control board through data lines, the first detection board and the first control board are connected with the first adapter through communication interfaces, and the first adapter is connected with the switch through network lines;

the second detection board and the second interface board are connected with the second control board through data lines, the second detection board and the second control board are connected with the second adapter through communication interfaces, and the second adapter is connected with the switch through network lines;

the switch is connected with the communication manager through a network cable;

the switch is configured to communicate with an energy management system via a first communication protocol and the communication manager is configured to communicate with the energy management system or a coordinator controller via a second communication protocol.

According to the multi-communication protocol debugging equipment, desktop debugging of communication protocols such as Modbus TCP, IEC18650MMS, IEC18650GOOSE and IEC104 between the PCS and the EMS and between the PCS and the coordination controller is realized through the detection board, the control board, the interface board, the adapter, the switch and the communication manager, so that field debugging time is saved, and field debugging progress is accelerated.

Drawings

Fig. 1 is a schematic diagram of an energy storage system according to an embodiment of the present application;

fig. 2 is a schematic diagram of a multi-communication protocol debugging device according to an embodiment of the present application;

fig. 3 is a schematic diagram of another multi-communication protocol debugging device according to an embodiment of the present application.

The realization, functional characteristics and advantages of the present application will be further described with reference to the embodiments, referring to the attached drawings.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved by the application clearer and more obvious, the application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

In the description of the present application, it should be understood that the directions or positional relationships indicated by the terms "center", "upper", "lower", "front", "rear", "left", "right", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of description of the present application and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application. Furthermore, 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.

1-2, an embodiment of the present application provides a multi-communication protocol debugging device, where the multi-communication protocol debugging device includes a detection board, a control board, an interface board, an adapter, a switch, and a communication manager;

the detection board and the interface board are connected with the control board through data lines, the detection board and the control board are connected with the adapter through a communication interface, and the adapter, the switch and the communication manager are connected through network cables;

the switch is configured to communicate with an energy management system via a first communication protocol and the communication manager is configured to communicate with the energy management system or a coordinator controller via a second communication protocol.

In one example, the sensing board and the interface board are connected to the control board by a flat cable. The sensing board is configured to transmit sensing data of the energy storage converter to the control board, the interface board is configured to transmit input and/or output signal amounts of the energy storage converter to the control board, and the control board is configured to transmit communication data of the energy storage converter to the adapter.

In one example, the control board is a DSP board.

In one example, the sensing board is connected to the adapter through a serial communication interface, such as RS485. The control board is connected with the adapter through an optical fiber, and an energy storage converter (PCS) can interact with the adapter through the control board.

In an example, the detection data of the energy storage converter includes at least one of ac voltage, dc voltage, current, and temperature.

In an example, the multi-communication protocol debugging device further comprises a first power conversion module and a second power conversion module;

the first power supply conversion module is used for providing a first power supply to supply power to the detection board, the control board and the interface board;

the second power conversion module is used for providing a second power supply to supply power to the adapter, the switch and the communication manager.

Wherein the first supply voltage is less than the second supply voltage. For example, the first power supply voltage is 15V, and the second power supply voltage is 24V.

In an example, the first communication protocol includes a Modbus TCP communication protocol, and the second communication protocol includes at least one of IEC61850 MMS, IEC61850 GOOSE, IEC 104.

When Modbus TCP communication is carried out, the data point table of the PCS is checked, communication data is confirmed, communication can be carried out with the upper controller, a communication manager is not needed at this time, the adapter Eth2 can directly carry out Modbus TCP communication, and the correctness of the data is confirmed through the background until all data communication is normal.

When IEC61850 (MMS, GOOSE) communication is carried out, the data point table of the PCS is converted into an icd file, the telemetering, remote control, remote adjustment and remote signaling quantity are confirmed, the data point table is burnt to a communication manager, the communication can be carried out with an upper controller, and the correctness of the data is confirmed through a background until all data communication is normal.

When IEC104 communication is carried out, the data point table of the PCS is configured into a db3 file by the communication manager, the telemetering, remote control, remote adjustment and remote signaling quantity are confirmed, the data point table is burnt to the communication manager, the communication can be carried out with the upper controller, and the correctness of the data is confirmed through the background until all the data communication is normal.

As shown in fig. 3, another embodiment of the present application provides a multi-communication protocol debugging device, where the multi-communication protocol debugging device includes a first detection board, a first control board, a first interface board, a first adapter, a second detection board, a second control board, a second interface board, a second adapter, a switch, and a communication manager;

the first detection board and the first interface board are connected with the first control board through data lines, the first detection board and the first control board are connected with the first adapter through communication interfaces, and the first adapter is connected with the switch through network lines;

the second detection board and the second interface board are connected with the second control board through data lines, the second detection board and the second control board are connected with the second adapter through communication interfaces, and the second adapter is connected with the switch through network lines;

the switch is connected with the communication manager through a network cable;

the switch is configured to communicate with an energy management system via a first communication protocol and the communication manager is configured to communicate with the energy management system or a coordinator controller via a second communication protocol.

In the example of fig. 3, the above device may refer to the example of fig. 2 and the description.

In an example, the multi-communication protocol debugging device further comprises a first power conversion module, a second power conversion module, a third power conversion module and a fourth power conversion module;

the first power supply conversion module is used for providing a first power supply to supply power to the first detection board, the first control board and the first interface board;

the second power conversion module is used for providing a second power supply to supply power to the first adapter;

the third power conversion module is used for providing a first power supply to supply power to the second detection board, the second control board and the second interface board;

the fourth power conversion module is used for providing a second power supply to supply power to the second adapter, the switch and the communication manager.

Wherein the first supply voltage is less than the second supply voltage. For example, the first power supply voltage is 15V, and the second power supply voltage is 24V.

The preferred embodiments of the present application have been described above with reference to the accompanying drawings, and are not thereby limiting the scope of the claims of the present application. Any modifications, equivalent substitutions and improvements made by those skilled in the art without departing from the scope and spirit of the present application shall fall within the scope of the claims of the present application.

Claims (10)

1. The multi-communication protocol debugging equipment is characterized by comprising a detection board, a control board, an interface board, an adapter, a switch and a communication manager;

the detection board and the interface board are connected with the control board through data lines, the detection board and the control board are connected with the adapter through a communication interface, and the adapter, the switch and the communication manager are connected through network cables;

the switch is configured to communicate with an energy management system via a first communication protocol and the communication manager is configured to communicate with the energy management system or a coordinator controller via a second communication protocol.

2. The multiple communication protocol commissioning device of claim 1, wherein the detection board is configured to transmit detection data of an energy storage converter to the control board, wherein the interface board is configured to transmit input and or output signal amounts of the energy storage converter to the control board, and wherein the control board is configured to transmit communication data of the energy storage converter to the adapter.

3. The multiple communication protocol debugging apparatus of claim 1, wherein the detection board and the interface board are connected to the control board by a flat cable.

4. The multiple communication protocol debugging apparatus of claim 1, wherein the detection board is connected with the adapter through a serial communication interface, and the control board is connected with the adapter through an optical fiber.

5. The multi-communication protocol debugging device of claim 2, wherein the detection data of the energy storage converter comprises at least one of ac voltage, dc voltage, current, temperature.

6. The multi-communication protocol debugging device of claim 1, wherein the first communication protocol comprises a Modbus TCP communication protocol and the second communication protocol comprises at least one of IEC61850 MMS, IEC61850 GOOSE, IEC 104.

7. The multi-communication protocol debugging device of claim 1, further comprising a first power conversion module and a second power conversion module;

the first power supply conversion module is used for providing a first power supply to supply power to the detection board, the control board and the interface board;

the second power conversion module is used for providing a second power supply to supply power to the adapter, the switch and the communication manager.

8. The multiple communication protocol debugging apparatus of claim 7, wherein the first power supply voltage is less than the second power supply voltage.

9. The multi-communication protocol debugging equipment is characterized by comprising a first detection plate, a first control plate, a first interface plate, a first adapter, a second detection plate, a second control plate, a second interface plate, a second adapter, a switch and a communication manager;

the first detection board and the first interface board are connected with the first control board through data lines, the first detection board and the first control board are connected with the first adapter through communication interfaces, and the first adapter is connected with the switch through network lines;

the second detection board and the second interface board are connected with the second control board through data lines, the second detection board and the second control board are connected with the second adapter through communication interfaces, and the second adapter is connected with the switch through network lines;

the switch is connected with the communication manager through a network cable;

the switch is configured to communicate with an energy management system via a first communication protocol and the communication manager is configured to communicate with the energy management system or a coordinator controller via a second communication protocol.

10. The multi-communication protocol debugging device of claim 9, further comprising a first power conversion module, a second power conversion module, a third power conversion module, and a fourth power conversion module;

the first power supply conversion module is used for providing a first power supply to supply power to the first detection board, the first control board and the first interface board;

the second power conversion module is used for providing a second power supply to supply power to the first adapter;

the third power conversion module is used for providing a first power supply to supply power to the second detection board, the second control board and the second interface board;

the fourth power conversion module is used for providing a second power supply to supply power to the second adapter, the switch and the communication manager.