CN111832156A - Electric power simulation system based on big data architecture - Google Patents

Abstract

The invention discloses a power simulation system based on a big data architecture, which comprises a simulation system monitoring module, a measurement data conversion module and a system state display module, wherein the simulation system monitoring module is connected with the system state display module through the measurement data conversion module, the simulation system monitoring module is used for monitoring and acquiring various index data in a simulation system and sending the acquired index data to the measurement data conversion module, the measurement data conversion module is used for converting and changing the data types of the index data, and the system state display module receives and displays the various index data and compares the various index data with standard data. The system state display module receives and displays the index data, compares the index data with the standard data, estimates the running state of the simulation system, and checks the simulation system in time when the simulation system fails.

Description

Electric power simulation system based on big data architecture

Technical Field

The invention relates to the technical field of power systems, in particular to a power simulation system based on a big data architecture.

Background

The power system simulation means that a virtual reality technology is utilized to virtualize industrial plants and equipment in the real world in a computer, a database technology and a data acquisition and monitoring control technology are utilized to transmit the running state parameters of production equipment back to a virtual power station system in real time, and query and management of the equipment can be realized in a three-dimensional virtual scene.

With the increasing capacity of unit generator sets and the increasing complexity of the system, higher requirements are put forward on economic operation and safe production of the unit generator sets, and the simulation system is the best way for achieving the purpose. The operation process can be optimized through the simulation system, and operators can be trained. The power station simulation system becomes necessary matched equipment in the construction and operation of the power station. Most of early training simulators contain simulation of a DCS, but the early training simulators are often simpler, are basically 'black box' models and have great difference with actual systems.

Therefore, in view of the above situation, there is an urgent need to develop a power simulation system based on a big data architecture to overcome the shortcomings in the current practical application.

Disclosure of Invention

The present invention is directed to a power simulation system based on big data architecture, so as to solve the problems mentioned in the background art.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides an electric power simulation analog system based on big data framework, includes simulation system monitoring module, measured data conversion module and system status display module, be connected through measured data conversion module between simulation system monitoring module and the system status display module, simulation system monitoring module is used for monitoring each item index data in the collection simulation system to send the index data that obtain to measured data conversion module, measured data conversion module is used for changing the data type of index data, system status display module shows after receiving each item index data, compares each item index data with standard data simultaneously.

As a further scheme of the invention: the simulation system monitoring module comprises an electric power information automatic measuring unit, a non-electric power information automatic measuring unit, a manual measuring unit and a signal sending unit, wherein the electric power information automatic measuring unit, the non-electric power information automatic measuring unit and the manual measuring unit are all connected with the signal sending unit I.

As a further scheme of the invention: the automatic power information measuring unit comprises a power measuring component, a voltage measuring component and a resistance measuring component, and the power measuring component, the voltage measuring component and the resistance measuring component are arranged at each test point of the simulation system.

As a further scheme of the invention: the non-electric power information automatic measuring unit is used for collecting temperature information of each device and instrument in the simulation system.

As a further scheme of the invention: the manual measuring unit comprises a system wiring verification assembly and a wiring terminal electricity verification assembly.

As a further scheme of the invention: the wiring electronic electricity testing component is an electricity testing pen.

As a further scheme of the invention: the measurement data conversion module comprises a signal receiving unit I, an A/D conversion unit and a signal sending unit II.

As a further scheme of the invention: the signal receiving unit I, the A/D conversion unit and the signal sending unit II are sequentially connected and used for receiving and converting the monitoring data signals.

As a further scheme of the invention: the system state display module comprises a signal receiving unit II, a standard value input unit, a comparison unit, a result display unit and an adjusting unit.

As a further scheme of the invention: and the signal receiving unit II and the standard value input unit are both connected with the comparison unit, the comparison unit is connected with the result display unit, and the result display unit is connected with the adjustment unit.

Compared with the prior art, the invention has the beneficial effects that: the simulation system monitoring module is arranged to monitor all data of equipment and instruments in the simulation system in real time when the equipment and the instruments work, monitoring results are sent to the system state display module, the system state display module receives all index data and displays the index data, meanwhile, all index data are compared with standard data, the running state of the simulation system is estimated, and troubleshooting is performed in time when the simulation system fails.

Drawings

FIG. 1 is a system block diagram of a big data architecture based power simulation system.

FIG. 2 is a system block diagram of a simulation system monitoring module in the power simulation system based on the big data architecture.

Fig. 3 is a system block diagram of an automatic power information measuring unit in a power simulation system based on a big data architecture.

FIG. 4 is a system block diagram of a manual measurement unit in a power simulation system based on a big data architecture.

FIG. 5 is a system block diagram of a measurement data conversion module in a big data architecture based power simulation system.

FIG. 6 is a system block diagram of a system status display module in the big data architecture-based power simulation system.

In the figure:

1-simulation system monitoring module,

11-automatic power information measuring unit,

111-current measuring component,

112-a voltage measuring component,

113-a resistance measuring component,

12-non-power information automatic measuring unit,

13-manual measuring unit,

131-system wiring verification component,

132-a wiring electronic electricity testing component,

14-signal transmitting unit I,

2-measured data conversion module,

21-signal receiving unit I,

22-A/D conversion unit,

23-Signal transmitting Unit II,

3-a system state display module,

31-signal receiving unit II,

32-standard value input unit,

33-comparison unit,

34-result display unit,

35-an adjusting unit.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

Example 1

Referring to fig. 1 to 4, in the embodiment of the present invention, an electric power simulation system based on a big data architecture includes a simulation system monitoring module 1, a measurement data conversion module 2, and a system status display module 3, where the simulation system monitoring module 1 and the system status display module 3 are connected through the measurement data conversion module 2;

the simulation system monitoring module 1 is used for monitoring and acquiring various index data in the simulation system and sending the acquired index data to the measurement data conversion module 2;

the measurement data conversion module 2 is used for converting and changing the data type of the index data, so that the index data can be received and displayed by the system state display module 3;

the system state display module 3 receives and displays the index data, compares the index data with the standard data, estimates the running state of the simulation system, and checks the simulation system in time when the simulation system fails;

the simulation system monitoring module 1 comprises an electric power information automatic measuring unit 11, a non-electric power information automatic measuring unit 12, a manual measuring unit 13 and a signal sending unit 14, wherein the electric power information automatic measuring unit 11, the non-electric power information automatic measuring unit 12 and the manual measuring unit 13 are all connected with the signal sending unit 14;

the power information automatic measurement unit 11 is configured to collect power data of devices and meters, in this embodiment, the power information automatic measurement unit 11 includes a power measurement component 111, a voltage measurement component 112, and a resistance measurement component 113, and the power measurement component 111, the voltage measurement component 112, and the resistance measurement component 113 are disposed at each test point of the simulation system;

the non-electric power information automatic measurement unit 12 is used for collecting temperature information of each device and instrument in the simulation system, assisting workers to know the temperature information of the devices and the instruments in time and avoiding overheating and damage of the devices and the instruments;

the manual measurement unit 13 comprises a system wiring verification component 131 and a wiring terminal electricity testing component 132, and after the wiring of the simulation system is finished, the wiring of the simulation system is compared with the standard wiring through the system wiring verification component 131, so that the phenomenon of wiring errors is avoided; the wiring terminal electricity testing component 132 is used for detecting whether each wiring terminal in the simulation system has electricity, and in this embodiment, the wiring electronic electricity testing component 132 is an electricity testing pen.

Example 2

Referring to fig. 1 to 4, in the embodiment of the present invention, an electric power simulation system based on a big data architecture includes a simulation system monitoring module 1, a measurement data conversion module 2, and a system status display module 3, where the simulation system monitoring module 1 and the system status display module 3 are connected through the measurement data conversion module 2;

the simulation system monitoring module 1 is used for monitoring and acquiring various index data in the simulation system and sending the acquired index data to the measurement data conversion module 2;

the measurement data conversion module 2 is used for converting and changing the data type of the index data, so that the index data can be received and displayed by the system state display module 3;

the system state display module 3 receives and displays the index data, compares the index data with the standard data, estimates the running state of the simulation system, and checks the simulation system in time when the simulation system fails;

the simulation system monitoring module 1 comprises an electric power information automatic measuring unit 11, a non-electric power information automatic measuring unit 12, a manual measuring unit 13 and a signal sending unit 14, wherein the electric power information automatic measuring unit 11, the non-electric power information automatic measuring unit 12 and the manual measuring unit 13 are all connected with the signal sending unit I14;

the power information automatic measurement unit 11 is configured to collect power data of devices and meters, in this embodiment, the power information automatic measurement unit 11 includes a power measurement component 111, a voltage measurement component 112, and a resistance measurement component 113, and the power measurement component 111, the voltage measurement component 112, and the resistance measurement component 113 are disposed at each test point of the simulation system;

the non-electric power information automatic measurement unit 12 is used for collecting temperature information of each device and instrument in the simulation system, assisting workers to know the temperature information of the devices and the instruments in time and avoiding overheating and damage of the devices and the instruments;

the manual measurement unit 13 comprises a system wiring verification component 131 and a wiring terminal electricity testing component 132, and after the wiring of the simulation system is finished, the wiring of the simulation system is compared with the standard wiring through the system wiring verification component 131, so that the phenomenon of wiring errors is avoided; the wiring terminal electricity testing component 132 is used for detecting whether each wiring terminal in the simulation system has electricity, and in this embodiment, the wiring electronic electricity testing component 132 is an electricity testing pen.

Referring to fig. 5, the difference between the present embodiment and embodiment 1 is:

the measurement data conversion module 2 comprises a signal receiving unit I21, an A/D conversion unit 22 and a signal sending unit II 23, wherein the signal receiving unit I21, the A/D conversion unit 22 and the signal sending unit II 23 are sequentially connected and used for receiving and converting monitoring data signals.

Example 3

Referring to fig. 1 to 4, in the embodiment of the present invention, an electric power simulation system based on a big data architecture includes a simulation system monitoring module 1, a measurement data conversion module 2, and a system status display module 3, where the simulation system monitoring module 1 and the system status display module 3 are connected through the measurement data conversion module 2;

the simulation system monitoring module 1 is used for monitoring and acquiring various index data in the simulation system and sending the acquired index data to the measurement data conversion module 2;

the measurement data conversion module 2 is used for converting and changing the data type of the index data, so that the index data can be received and displayed by the system state display module 3;

the system state display module 3 receives and displays the index data, compares the index data with the standard data, estimates the running state of the simulation system, and checks the simulation system in time when the simulation system fails;

the simulation system monitoring module 1 comprises an electric power information automatic measuring unit 11, a non-electric power information automatic measuring unit 12, a manual measuring unit 13 and a signal sending unit 14, wherein the electric power information automatic measuring unit 11, the non-electric power information automatic measuring unit 12 and the manual measuring unit 13 are all connected with the signal sending unit I14;

the power information automatic measurement unit 11 is configured to collect power data of devices and meters, in this embodiment, the power information automatic measurement unit 11 includes a power measurement component 111, a voltage measurement component 112, and a resistance measurement component 113, and the power measurement component 111, the voltage measurement component 112, and the resistance measurement component 113 are disposed at each test point of the simulation system;

the non-electric power information automatic measurement unit 12 is used for collecting temperature information of each device and instrument in the simulation system, assisting workers to know the temperature information of the devices and the instruments in time and avoiding overheating and damage of the devices and the instruments;

the manual measurement unit 13 comprises a system wiring verification component 131 and a wiring terminal electricity testing component 132, and after the wiring of the simulation system is finished, the wiring of the simulation system is compared with the standard wiring through the system wiring verification component 131, so that the phenomenon of wiring errors is avoided; the wiring terminal electricity testing component 132 is used for detecting whether each wiring terminal in the simulation system has electricity, and in this embodiment, the wiring electronic electricity testing component 132 is an electricity testing pen.

Referring to fig. 5, embodiment 2 is different from embodiment 1 in that:

the measurement data conversion module 2 comprises a signal receiving unit I21, an A/D conversion unit 22 and a signal sending unit II 23, wherein the signal receiving unit I21, the A/D conversion unit 22 and the signal sending unit II 23 are sequentially connected and used for receiving and converting monitoring data signals.

Referring to fig. 6, the difference between the present embodiment and embodiments 1-2 is:

the system state display module 3 comprises a signal receiving unit II 31, a standard value input unit 32, a comparison unit 33, a result display unit 34 and an adjusting unit 35, wherein the signal receiving unit II 31 and the standard value input unit 32 are both connected with the comparison unit 33, the comparison unit 33 is connected with the result display unit 34, and the result display unit 34 is connected with the adjusting unit 35.

The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, it is possible to make several variations and modifications without departing from the concept of the present invention, and these should be considered as the protection scope of the present invention, which will not affect the effect of the implementation of the present invention and the utility of the patent.

Claims (10)

1. The utility model provides an electric power simulation analog system based on big data framework, its characterized in that, includes simulation system monitoring module (1), measured data conversion module (2) and system status display module (3), connect through measured data conversion module (2) between simulation system monitoring module (1) and the system status display module (3), simulation system monitoring module (1) is arranged in monitoring each item index data of gathering simulation system to send the index data that obtains to measured data conversion module (2), measured data conversion module (2) are used for changing the data type of index data, system status display module (3) are shown after receiving each item index data, compare each item index data with standard data simultaneously.

2. The big data architecture-based power simulation system according to claim 1, wherein the simulation system monitoring module (1) comprises an automatic power information measuring unit (11), an automatic non-power information measuring unit (12), a manual power information measuring unit (13) and a signal transmitting unit (14), and the automatic power information measuring unit (11), the automatic non-power information measuring unit (12) and the manual power information measuring unit (13) are all connected with the signal transmitting unit I (14).

3. The big data architecture-based power simulation system according to claim 2, wherein the power information automatic measurement unit (11) comprises a power measurement component (111), a voltage measurement component (112) and a resistance measurement component (113), and the power measurement component (111), the voltage measurement component (112) and the resistance measurement component (113) are arranged at each test point of the simulation system.

4. The big data architecture based power simulation system according to claim 3, wherein the non-power information automatic measurement unit (12) is used for collecting temperature information of each device and instrument in the simulation system.

5. The big data architecture based power simulation system of claim 4, wherein the manual measurement unit (13) comprises a system wiring verification component (131) and a terminal electricity verification component (132).

6. The big data architecture based power simulation system of claim 5, wherein the wired electronic electroscope component (132) is an electroscope pen.

7. The big data architecture-based power simulation system according to claim 1, wherein the measurement data conversion module (2) comprises a signal receiving unit I (21), an A/D conversion unit (22) and a signal transmitting unit II (23).

8. The big data architecture-based power simulation system according to claim 1, wherein the signal receiving unit i (21), the a/D conversion unit (22) and the signal sending unit ii (23) are connected in sequence for receiving and converting the monitoring data signal.

9. The big data architecture-based power simulation system according to claim 1, wherein the system status display module (3) comprises a signal receiving unit II (31), a standard value input unit (32), a comparison unit (33), a result display unit (34) and an adjustment unit (35).

10. The big data architecture-based power simulation system according to claim 9, wherein the signal receiving unit ii (31) and the standard value input unit (32) are both connected to the comparison unit (33), the comparison unit (33) is connected to the result display unit (34), and the result display unit (34) is connected to the adjustment unit (35).

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