CN110532695B - Electrical system diagram software configuration method - Google Patents

Abstract

The invention discloses an electrical system diagram software configuration method, which comprises the following steps: step S1: configuring an electrical system map base map, wherein the input configuration of the electrical system map base map comprises a base map type, a map name, a cabinet name, a block number and a block coordinate; step S2: the electrical system diagram blocks are configured. The electrical system diagram software configuration method disclosed by the invention has the beneficial effects of simple configuration, optimized display and dynamic supervision.

Description

Electrical system diagram software configuration method

Technical Field

The invention belongs to the technical field of automatic processing of electrical system diagrams, and particularly relates to a method for configuring electrical system diagram software.

Background

The power supply and distribution systems of the sites are different aiming at the distribution stations such as a switch station, a distribution room, a box-type transformer substation and the like, and the electric system diagrams of the sites are different. How to dynamically show an electrical system diagram through computer software has always been a difficult problem. The software configuration method of each manufacturer is complicated, and the display effect is not satisfactory, so that an electrical system diagram configuration method for simplifying the system diagram configuration, optimizing the display effect and realizing dynamic supervision is needed.

Disclosure of Invention

Aiming at the state of the art, the invention overcomes the defects and provides an electrical system diagram software configuration method.

The invention adopts the following technical scheme that the electrical system diagram software configuration method comprises the following steps:

step S1: configuring an electrical system map base map, wherein the input configuration of the electrical system map base map comprises a base map type, a map name, a cabinet name, a block number and a block coordinate;

step S2: the electrical system diagram blocks are configured.

According to the above technical solution, as a further preferable technical solution of the above technical solution, the input configuration of the electrical system diagram block includes a feeder name, an associated meter ID, an associated switching value ID, a bubble content, and a display parameter.

According to the above technical solution, as a further preferable technical solution of the above technical solution, the electrical system diagram block includes a longitudinal diagram block and a transverse diagram block, each longitudinal diagram block has a consistent height, each transverse diagram block has a consistent length, and the height of the transverse diagram block is a fraction of the height of the longitudinal diagram block.

According to the above technical scheme, as a further preferable technical scheme of the above technical scheme, the switch position, the alarm indicator light position, the bubble position, the parameter display position, and the feeder name position in the longitudinal block are all identical, and the switch position, the alarm indicator light position, the bubble position, the parameter display position, and the feeder name position in the transverse block are all identical.

According to the above technical scheme, as a further preferable technical scheme of the above technical scheme, the alarm indicator lamp position is used for displaying "power failure", "phase failure" and "trip".

According to the above aspect, as a further preferable aspect of the above aspect, the parameter display position is used for displaying the electric power parameter.

According to the above technical solution, as a further preferable technical solution of the above technical solution, the electrical system diagram software configuration method further includes the following steps:

step S3: and saving the configured electrical system diagram base map and electrical system diagram blocks to form a configuration file corresponding to each site.

The electrical system diagram software configuration method disclosed by the invention has the beneficial effects of simple configuration, optimized display and dynamic supervision.

Drawings

Fig. 1 is a diagram of a high voltage electrical system of the present invention.

Fig. 2 is a view (1) of the longitudinal piezoelectric system of the present invention.

Fig. 3 is a view (2) of the longitudinal piezoelectric system of the present invention.

Fig. 4 is a view (1) of the lateral piezoelectric system of the present invention.

Fig. 5 is a view (2) of the lateral piezoelectric system of the present invention.

Fig. 6A-6D are switch state blocks of the present invention.

Fig. 7 is a functional schematic of the present invention.

Fig. 8 is a configuration diagram of the present invention.

Fig. 9A-9Z are power cabinet functional blocks of the present invention.

Detailed Description

The invention discloses a software configuration method for an electrical system diagram, and a specific implementation of the invention is further described below with reference to a preferred embodiment.

Referring to fig. 1 to 9Z of the drawings, fig. 1 shows a high-voltage electrical system of the electrical system diagram software configuration method, fig. 2 shows a longitudinal low-voltage electrical system (1) of the electrical system diagram software configuration method, fig. 3 shows a longitudinal low-voltage electrical system (2) of the electrical system diagram software configuration method, fig. 4 shows a transverse low-voltage electrical system diagram (1) of the electrical system diagram software configuration method, fig. 5 shows a transverse low-voltage electrical system diagram (2) of the electrical system diagram software configuration method, fig. 6A to 6D respectively show on-off status blocks of the electrical system diagram software configuration method, fig. 7 shows main functions of the electrical system diagram software configuration method, fig. 8 shows a configuration mode of the electrical system diagram software configuration method, and fig. 9 shows a power cabinet function block as a schematic of the electrical system diagram software configuration method.

Preferred embodiments.

Preferably, the electrical system diagram software configuration method comprises the following steps:

step S1: configuring an electrical system map base map, wherein input configuration of the electrical system map base map includes, but is not limited to, base map type, map name, cabinet name, block number and block coordinates;

step S2: the electrical system diagram blocks are configured.

Further, the input configuration of the electrical system map tiles includes, but is not limited to, feeder names, associated meter IDs, associated switch quantity IDs, bubble content, display parameters.

Further, the electrical system map blocks include longitudinal blocks and transverse blocks, each longitudinal block has a consistent height, each transverse block has a consistent length, and the transverse block height is a fraction of the longitudinal block height.

Further, the switch position, the alarm indicator light position, the bubble position, the parameter display position and the feeder line name position in the longitudinal block are all consistent, and the switch position, the alarm indicator light position, the bubble position, the parameter display position and the feeder line name position in the transverse block are all consistent.

Further, the switch position is used for displaying the opening and closing state; the alarm indicator lamp is used for displaying power failure, phase failure and tripping; the bubble position is used for displaying all parameters; the parameter display is used for displaying key power parameters: three-phase voltage maximum value, three-phase current maximum value and active power degree; the feeder name location is used to display the feeder loop name.

Further, the electrical system diagram software configuration method further comprises the following steps:

step S3: and storing the configured electric system diagram base diagram and electric system diagram blocks to form configuration files corresponding to each site, and flexibly realizing different user differential performance requirements.

According to the embodiment, the working principle of the electrical system diagram software configuration method disclosed by the patent application is specifically described as follows.

The electrical system diagram software configuration method comprises the steps of configuring an electrical system diagram base diagram and configuring electrical system diagram blocks.

Wherein, the electrical system map base map includes but is not limited to input configuration of base map type, map name, cabinet name, block number, block coordinates, etc.

Further, the types of the base patterns are at least divided into a high-voltage electric system pattern (see fig. 1), a longitudinal-voltage electric system pattern (see fig. 2, 3), and a lateral-voltage electric system pattern (see fig. 4, 5).

Wherein the electrical system map tiles include, but are not limited to, feeder names, associated meter IDs, associated switch quantity IDs, bubble content, display parameters, etc. input configurations.

Further, the electrical system map blocks include, but are not limited to, a switch closed state map, a switch open state map, and the block numbers and the switch states are respectively written and associated with key parameters of the associated meter ID and the switching value ID.

Wherein the electrical system diagram blocks include a portrait block and a landscape block.

Further, the heights of the individual longitudinal segments are uniform, and the widths of the individual longitudinal segments are integer multiples of the (preset) minimum width.

Further, the lengths of the individual transverse tiles are uniform, with the height of each transverse tile being a fraction of the height of the longitudinal tile.

Further, the switch position, alarm indicator light position, bubble position, parameter display position, feeder line name position in the longitudinal block are all consistent.

Further, the switch position, alarm indicator light position, bubble position, parameter display position, feeder line name position in the transverse pattern block are all consistent.

Further, the alarm indicator light position is used to display "power outage", "open phase", "trip" (see fig. 6).

Further, the parameter display position is used to display the power parameter.

It should be noted that the general technical concept of the present invention is as follows: after the bottom map of the electrical system map and the map blocks of the electrical system are configured, computer software calls different bottom maps according to the type of the configured bottom map, displays corresponding names according to the name and cabinet name of the map input by the configuration, determines the positions of the map blocks in the bottom map according to the configured coordinates, calls different map blocks according to the number of the configured map blocks, and finally forms the electrical system map; the called image block configures feeder line name, associated instrument ID, associated switch quantity ID, bubble content and display parameter, the bubble content, the display parameter, the alarm indicator lamp are selectively associated with the parameters acquired by the associated instrument ID and the associated switch quantity ID, the bubble adopts hidden design, and the bubble is displayed when the bubble needs to be checked. When any parameter in the bubble alarms, the alarm indicator light displays, and when no parameter in the bubble alarms, the alarm indicator light is hidden (see fig. 7).

The two states of the block are switched according to the three-phase voltage of the associated meter or the switching state of the associated switching value:

when the image block is simultaneously associated with the instrument and the switching value, and the three-phase voltage of the instrument is all zero and the switching value is normally closed, invoking the image block in a switch closing state, wherein the position of a warning indicator lamp in the image block displays red power failure (see fig. 6D); when the three-phase voltage of the instrument is all zero and the switching value is normally open, a switch off state block is called, and the position of a warning indicator lamp in the block displays yellow trip (see fig. 6B); 1 of the three-phase voltages of the instrument is zero or 2 of the three-phase voltages of the instrument are zero, a switch closing state image block is called, and the position of a warning indicator lamp in the image block displays red open phase (see fig. 6C);

when the image block is associated with the instrument and is not associated with the switching value, the three-phase voltage of the instrument is zero, a switch off state diagram is called, and the position of the warning indicator lamp in the image block displays yellow trip or red power failure; 1 of the three-phase voltages of the instrument is zero or 2 of the three-phase voltages of the instrument are zero, a switch closing state diagram is called, and the position of a warning indicator lamp in a picture block displays red phase failure;

when the image block is not related to the instrument and is related to the switching value, calling the image block in a switch closing state when the switching value is normally closed, wherein the position of the warning indicator lamp in the image block does not display any content; when the switching value is normally open, a switch off state image block is called, and the position of the warning indicator lamp in the image block displays yellow trip.

In this embodiment, there are a total of 3 electrical system diagrams, i.e., a high voltage electrical system diagram, a longitudinal low voltage electrical system diagram (group 2), and a transverse low voltage electrical system (group 2).

The high-voltage electric system diagram is preferably provided with 12 longitudinal blocks, the longitudinal low-voltage electric system diagram is preferably provided with 28 longitudinal blocks, and the transverse low-voltage electric system diagram is preferably provided with 3 longitudinal blocks and 36 transverse blocks.

The standard vertical pattern block size is 64×430, the standard horizontal pattern block size is 261×43, and the bus pattern block, the dual power pattern block, and the capacitor box pattern block size is 86×430 (unit: pixel).

Each electrical system map base map is provided with input configurations such as base map type, map name, cabinet name, block number, block coordinates and the like.

Each tile is provided with an input configuration of feeder line name, associated meter ID, associated switch value ID, bubble content, display parameters, etc.

It should be noted that technical features such as pixels related to the present application should be considered as the prior art, and specific structures, working principles, and control manners and spatial arrangements of the technical features may be selected conventionally in the art, and should not be considered as the point of the present application, which is not further specifically described in detail herein.

Modifications of the embodiments described above, or equivalents of some of the features may be made by those skilled in the art, and any modifications, equivalents, improvements or etc. within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (5)

1. A method for configuring electrical system diagram software, comprising the steps of:

step S1: configuring an electrical system map base map, wherein the input configuration of the electrical system map base map comprises a base map type, a map name, a cabinet name, a block number and a block coordinate;

step S2: configuring an electrical system diagram block;

after the bottom map of the electrical system is configured and the map blocks of the electrical system are configured, computer software calls different bottom maps according to the type of the configured bottom map, displays corresponding names according to the name and cabinet name of the configured input map, determines the positions of the map blocks in the bottom map according to the configured coordinates, calls different map blocks according to the number of the configured map blocks, and finally forms the electrical system map; the called image block configures a feeder line name, an associated instrument ID, an associated switching value ID, bubble content and display parameters, the bubble content, the display parameters and alarm indicator lamps are selectively associated with the parameters acquired by the associated instrument ID and the associated switching value ID, the bubbles are displayed by adopting hidden designs when needing to be checked, the alarm indicator lamps are displayed when any parameter in the bubbles alarms, and the alarm indicator lamps are hidden when no parameter in the bubbles alarms;

the two states of the block are switched according to the three-phase voltage of the associated meter or the switching state of the associated switching value:

when the image block is simultaneously associated with the instrument and the switching value, and the three-phase voltage of the instrument is all zero and the switching value is normally closed, invoking the image block in a switch closing state, and displaying red power failure at the position of a warning indicator lamp in the image block; when the three-phase voltage of the instrument is all zero and the switching value is normally open, a switch off state block is called, and the position of a warning indicator lamp in the block displays yellow trip; 1 of the three-phase voltages of the instrument is zero or 2 of the three-phase voltages of the instrument are zero, a switch closing state image block is called, and the position of a warning indicator lamp in the image block displays red phase failure;

when the image block is associated with the instrument and is not associated with the switching value, the three-phase voltage of the instrument is zero, the image block of the switch off state is called, and the position of the warning indicator lamp in the image block displays yellow trip or red power failure; 1 of the three-phase voltages of the instrument is zero or 2 of the three-phase voltages of the instrument are zero, and the positions of warning indicator lamps in a switch closing state image block and an image block are called to display red 'open phases';

when the image block is not related to the instrument and is related to the switching value, calling the image block in a switch closing state when the switching value is normally closed, wherein the position of the warning indicator lamp in the image block does not display any content; when the switching value is normally open, a switch off state image block is called, and the position of the warning indicator lamp in the image block displays yellow trip.

2. The electrical system diagram software configuration method of claim 1 wherein the electrical system diagram tiles include longitudinal tiles and transverse tiles, each longitudinal tile being of uniform height, width being an integer multiple of a minimum width, each transverse tile being of uniform length and height being a fraction of the height of the longitudinal tile.

3. The electrical system diagram software configuration method of claim 2, wherein the switch position, the alarm indicator light position, the bubble position, the parameter display position, the feeder name position in the portrait tile are all identical, and the switch position, the alarm indicator light position, the bubble position, the parameter display position, the feeder name position in the landscape tile are all identical.

4. The electrical system diagram software configuration method of claim 3 wherein the switch position is used to display the open and closed states; the alarm indicator lamp is used for displaying power failure, phase failure and tripping;

the bubble position is used for displaying all parameters; the parameter display is used to display the power parameters.

5. The electrical system diagram software configuration method according to any one of claims 1 to 4, further comprising the steps of:

step S3: and saving the configured electrical system diagram base map and electrical system diagram blocks to form a configuration file corresponding to each site.

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