CN107784139B - Automatic generation method of electrical schematic diagram of compressor control system - Google Patents

Abstract

The invention relates to an automatic generation method of an electrical schematic diagram of a compressor control system, which comprises the following steps: importing a measuring point list of a compressor control system, and receiving input compressor control system design parameter information; generating an EXCEL form according to the content of the measuring point list and the input design parameter information; and generating an electrical schematic diagram in an EPLAN format according to the contents of the EXCEL table. According to the invention, an EXCEL form is not required to be filled in according to a format required by an EECONE template, only a measuring point list and design parameters are required to be filled in a computer human-computer interface, and then an EPLAN format compressor control system electrical schematic diagram can be generated through an automatic generation drawing of the EECONE. The user can automatically generate the electrical schematic diagram of the compressor control system only by simply selecting and inputting characters on a computer human-computer interface, thereby greatly improving the working efficiency and the design accuracy and shortening the design period.

Description

Automatic generation method of electrical schematic diagram of compressor control system

Technical Field

The invention belongs to the field of electrical software application, and particularly relates to an automatic generation method of an electrical schematic diagram of a compressor control system.

Background

The compressor control system is used as an indispensable part of the compressor and is widely applied to the fields of air separation, metallurgy, petroleum, chemical industry and the like. Large compressor control systems typically include more than 6 control cabinets and typically require a large number of control system electrical schematics.

The design drawing of the prior compressor control system is designed by a designer manually by adopting CAXA or AUTOCAD design software. Due to the functional limitations of the two types of software, the design time is often long. Therefore, the lead time of the design drawing is hardly secured while affecting the lead time of the entire compressor control system.

The design drawing of the prior compressor control system usually adopts a CAXA storage mode, which is difficult to satisfy the requirement that a designer effectively controls and manages the components contained in the design drawing, directly influences the integral integrity of the design drawing and is easy to cause the error of the design drawing; moreover, the numbering of various devices and equipment numbers of the control system needs a uniform numbering method, and errors are easy to occur if a manual numbering mode is adopted.

Disclosure of Invention

Aiming at the technical defects, the invention aims to provide an automatic generation method of an electrical schematic diagram of an automatic control system of a compressor, which can shorten the design period, improve the working efficiency and the design accuracy.

The technical scheme adopted by the invention for solving the technical problems is as follows: the automatic generation method of the electrical schematic diagram of the compressor control system comprises the following steps:

importing a measuring point list of a compressor control system, and receiving input compressor control system design parameter information;

generating an EXCEL form according to the content of the measuring point list and the input design parameter information;

and generating the design drawing in the EPLAN format according to the EXCEL table content.

The measuring point list comprises a plurality of measuring point categories, namely an AI measuring point, an AO measuring point, a PI measuring point, a DI measuring point, a DO measuring point and a unit state monitoring system measuring point; the loop corresponding to each measuring point comprises a loop position number, a loop name and a loop type.

The design parameter information includes:

terminal board information: the serial number of the control cabinet, the terminal access mode, and the serial number and the model of the control cabinet where the PLC terminal board is located;

loop information: the type of a safety barrier, the number of a clamping piece of a unit state monitoring system and the number of a channel of the unit state monitoring system required by each loop;

information of the alternating current power distribution module: each breaker is connected with an object and rated current;

information of a direct current power distribution module: the model and rated current of each power supply;

information of the relay module: a connection object of a relay and a contact connection object;

information of the direct current power distribution module: each terminal name, a terminal connection object, and a rated current.

The method for generating the EXCEL form according to the content of the measuring point list and the input design parameter information comprises the following steps:

1) allocating EXCEL tables according to the type of the design parameter information, wherein each table comprises one type of design parameter information;

2) and mapping the certain type of design parameter information and the corresponding content thereof in the measuring point list into the cells of the corresponding table.

The mapping to the cells of each form header according to the design parameter information and the corresponding content in the measuring point list specifically comprises the following steps:

1) distributing preset information of a certain type of measuring points into table head cells corresponding to the EXCEL table;

2) distributing item numbers and control cabinet sequence numbers in the measuring point list to page attribute cells corresponding to the macro names of the tables;

3) generating macro names of all tables according to the measuring point list and the design parameter information, and sequentially listing the macro names in the first-column cells under the corresponding table heads of all tables;

4) distributing the coordinates of each macro in the design drawing to the position cell corresponding to the macro;

5) and distributing the position number and the loop name of each loop in the measuring point list to the macro attribute corresponding to the macro name of each table.

The macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first-column cells below the corresponding table heads of the tables:

1) classifying and sorting the loops according to the types of the measuring point lists to be used as macro names, and sequentially listing the macro names in the first-row cells below the corresponding heads;

2) taking the model of the loop safety barrier selected by the user as a macro name, and sequentially listing the macro name in the first row of cells under the corresponding header;

3) the user selects a terminal access mode, the loop names in the measuring point list are classified sometimes, the terminals in each class are sequenced and numbered, and the next step is executed; if not, executing the next step;

4) and (4) taking the variable value obtained by carrying out ASCII code inverse calculation on the difference between the initial measuring point and the ending measuring point of the shield line in the measuring point list as the macro variable content of the shield line.

The macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first-column cells below the corresponding table heads of the tables:

the circuit breaker connection objects selected by a user are used as macro names and are sequentially listed in the first-row cells under the corresponding heads; and distributing each rated current input by a user into the macro attribute corresponding to the model of the loop safety barrier.

The macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first-column cells below the corresponding table heads of the tables:

the types of the power supplies selected by the user are used as macro names and are sequentially listed in the first row of cells under the corresponding header; and distributing each rated current input by a user into the macro attribute corresponding to the model of the loop safety barrier.

The macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first-column cells below the corresponding table heads of the tables:

according to the connection object of the relay selected by the user as a macro name, sequentially listing the macro name in the first row of cells under the corresponding header; and distributing each contact connection object input by a user into the macro attribute corresponding to the model of the circuit safety barrier.

The macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first-column cells below the corresponding table heads of the tables:

combining each terminal name and the terminal connecting object selected by a user to be used as a macro name, and sequentially listing the macro names in the first-column cells under the corresponding header; and distributing each rated current input by a user into the macro attribute corresponding to the model of the loop safety barrier.

The invention has the following beneficial effects and advantages:

1. according to the invention, an EXCEL form is not required to be filled in according to a format required by an EECONE template, only a measuring point list and design parameters are required to be filled in a computer human-computer interface, and then an EPLAN format compressor control system electrical schematic diagram can be generated through an automatic generation drawing of the EECONE.

2. The invention uses VISUAL STUDIO as a design platform, adopts a C # programming tool, realizes automatic layout of the design drawing page layout, automatic generation of a safety grid position number, a terminal row number, a terminal number, associated connection and the like by calling the function of EECONE, and can automatically generate the electrical schematic diagram of the compressor control system by a user only by simply selecting and inputting characters on a computer human-computer interface, thereby greatly improving the working efficiency and the design accuracy and shortening the design period.

Drawings

FIG. 1 is a system block diagram of the present invention;

FIG. 2 is a logic flow diagram of an embodiment of the present invention;

FIG. 3 is a diagram illustrating an EXCEL form on an EECONE platform that is automatically generated according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a thermal resistance measuring point loop macro file preset according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of an EPLAN formatted PLC terminal block automatically generated by an embodiment of the present invention;

FIG. 6 is a schematic diagram of a 220V AC distribution network in EPLAN format automatically generated by an embodiment of the present invention;

FIG. 7 is a schematic diagram of an automatically generated 220V-24V DC power supply in EPLAN format according to an embodiment of the present invention;

FIG. 8a is a schematic diagram of a relay in EPLAN format that is automatically generated by an embodiment of the present invention;

FIG. 8b is a diagram of a second relay schematic in EPLAN format that is automatically generated in accordance with an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to examples.

The invention discloses an automatic generation method of an electrical schematic diagram of a compressor control system, which is based on a compressor control system design technology and a software technology, takes an independently developed human-computer interface and EPLAN software as a design platform, and comprises the following steps: 1. importing a measuring point list of a compressor control system; 2. inputting design parameters; 3. generating an EXCEL table meeting the EECONE template requirement; 4. invoking EECONE generates a schematic diagram in the EPLAN. The invention can automatically generate the electrical schematic diagram of the compressor control system in the EPLAN format only by simply selecting the loop type of the control system and inputting characters in a human-computer interface of a computer by a designer, thereby greatly reducing the workload of the designer of the compressor control system, saving the time and greatly improving the working efficiency.

A compressor control system electrical schematic diagram automatic generation method based on EECONE comprises EPLAN electrical drawing software, EECONE platform, EXCEL table, C # programming tool and computer man-machine interface, and is characterized in that: using a computer human-computer interface compiled by the C # programming tool to collect a measuring point list and design parameters compiled by a designer and automatically generating an EXCEL form conforming to an EECONE platform format; the EECONE platform is used as a part of EPLAN software and appears in the form of EXCEL table loading items, and macro files written in the EPLAN software by a designer can be automatically arranged in corresponding items of the EPLAN software.

A computer human-computer interface written by the C # programming tool comprises a plurality of drop-down lists, text boxes and other controls, so that the process of filling in the design parameter information of the control system by a designer is more concise, intuitive and targeted.

The computer human-computer interface is developed secondarily by a C # programming tool based on an EECONE platform, and a designer does not need to know the EXCEL table format required by the EECONE platform.

The design parameter information and the measuring point list content in the human-computer interface of the computer can be filled back into the EXCEL form according to a format which can be recognized by an EECONE platform.

The number and the types of various electric and control components in the electric principle diagram of the compressor control system can be automatically calculated and configured, the page layout can be automatically arranged, and the safety grid position number, the breaker position number, the power supply position number, the relay position number, the terminal row number, the terminal number and the associated connection can be automatically generated.

The method for automatically generating the electrical schematic diagram of the automatic control system of the compressor is based on the automatic system design technology and the computer technology, takes a computer human-computer interface as a design platform, and comprises the following operation steps:

1. and importing a measuring point list of a compressor control system. The measuring point list comprises measuring point types including an AI measuring point, an AO measuring point, a PI measuring point, a DI measuring point, a DO measuring point and a unit state monitoring system measuring point; the loop corresponding to each measuring point comprises a loop position number, a loop name and a loop type.

2. Inputting design parameters. Inputting the type of the safety barrier required by each loop into a human-computer interface, namely selecting the type of the safety barrier in the loop; inputting each circuit breaker function and rated current in a preset 220V alternating current power distribution module into a human-computer interface; inputting each power rated current in a preset 220V-24V direct current power supply module into a human-computer interface; inputting each terminal function and rated current in a preset 24V direct current power distribution module into a human-computer interface; and inputting the function, type and power supply mode of each relay in the preset relay module into the human-computer interface.

3. And generating an EXCEL table meeting the EECONE template requirement. And automatically generating an EXCEL table under the EECONE platform according to the imported measuring point list and the design parameters.

Calling EECONE to generate an electrical schematic diagram of the compressor automatic control system in the EPLAN.

The compressor control system design drawing automatic generation system has the architecture as shown in FIG. 1.

Fig. 2 is a flow chart of an embodiment of the method for automatically generating an electrical schematic diagram of a compressor control system according to the present invention.

The method comprises the following operation steps:

1. and importing a measuring point list of a compressor control system in a computer human-computer interface. The measurement point list in this embodiment includes 128 AI measurement point loops, 8 AO measurement point loops, 8 PI measurement point loops, and 64 DI measurement point loops, and 32 DO measurement point loops, and each loop includes a loop position number, a loop name, and a loop type.

2. And inputting the number of control cabinets, terminal access modes and the positions and types of PLC terminal boards required by the whole compressor control system into a computer human-computer interface. Each control cabinet number is automatically generated by the control cabinet number and can be manually edited; determining whether each measuring point is in non-terminal connection with the field device according to a terminal access mode; the number of the control cabinet and the model of the PLC terminal board where each PLC terminal board and each measuring point are located are determined by the position and the model of the PLC terminal board. The control system in this embodiment has 5 control cabinets, all the AI terminal boards, the AO terminal boards and the PI terminal boards are located in the same control cabinet, and all the DI terminal boards and the DO terminal boards are located in the same control cabinet.

3. And inputting the type of the safety barrier, the card number of the unit state monitoring system and the channel number of the unit state monitoring system required by each loop into a computer human-computer interface, namely, selecting the type of the safety barrier, the terminal board and the terminal in the loop. Determining the type of the safety barrier of each measuring point of the safety barrier according to the type of the safety barrier; determining the unit state monitoring system card serial number of each shafting vibration measurement and displacement measurement point according to the unit state monitoring system card serial number; determining the channel number of the unit state monitoring system of each shafting vibration measurement and displacement measurement point according to the channel number of the unit state monitoring system; the safety barrier position number and the outside cabinet unit position number can be automatically generated from the loop position number in the measuring point list. In the embodiment, the safety barriers of all the shafting temperature measuring points of the unit are KFD2-UT2-EX1 with the model number of P + F and are externally connected with a thermal resistance loop, as shown in FIG. 5.

Step 3, automatically generating an algorithm description: automatically identifying the type of the measuring point according to the ' input card identification number ' and the ' output card identification number ' of each measuring point in the imported measuring point list ', for example, automatically identifying the measuring point as an analog quantity input measuring point according to the ' AI ' description in ' AI 11 ', and automatically identifying the measuring point as a digital quantity output measuring point according to the ' DO ' description in ' DO 15 '; and then, according to the functional mark and the graphic symbol of the HG-T20505-2000 process measurement and control instrument, combining the 'measurement point bit number' of each measurement point in the introduced 'measurement point list' to automatically identify the thermodynamic variable type or the control switching value type of the measurement point, for example, automatically identifying the measurement point as a temperature analog input measurement point according to the 'TE' description in '810 TE 1660A', automatically identifying the bit number as a prefix of '810', and a suffix of '1660A', replacing 'TE' as 'TB', and converting the bit number into '810 TB 1660A' in the 'safety barrier bit number' column in fig. 3 by combining the prefix and the suffix.

Automatically identifying the function of each measuring point according to the measuring point description in the measuring point list, for example, automatically identifying the measuring point as a compressor shafting temperature measuring point according to the compressor bearing temperature, determining the model of a safety barrier in a connected control cabinet as KFD2-UT2-EX1, and externally connecting a thermal resistor; and for example, a certain measuring point can be automatically identified as a low-temperature pipeline temperature measuring point according to the measuring point description in the measuring point list, and a low-temperature thermocouple or a platinum thermal resistor is externally connected according to the measuring range of the input measuring range in the measuring point list.

And then automatically arranging the position of each measuring point macro according to the number of the measuring points connected with the PLC terminal board, wherein for example, the initial cell value of the X column in FIG. 3 is 29, the increment of the cell value of each cell is 23, and the Y column is a fixed value 200, which indicates that the position of each measuring point loop macro in the vertical direction is the same. ("X" column and "Y" column are coordinates on the blueprint for each macro). And calculating the length and the initial position of the shield wire macro according to the number of the analog measuring points on each terminal board and the initial position of the measuring point. The length of the shielding line is controlled by 'variable', and the content 'H' of the cell of the 'variable' is obtained by solving the ASCII code inverse calculation according to the numerical value difference value of the positions of the starting measuring point and the ending measuring point; the X cells are the initial positions of the shielding lines and are calculated according to the positions of initial measuring points, and the Y cells are fixed values and represent that the positions of all the shielding lines in the vertical direction are the same.

The other columns in fig. 3 are a terminal row number column and a terminal number column (not shown in fig. 3) of each terminal in the measurement point loop, and can be classified and uniformly numbered through "position number description", and in general, the terminal row numbers of the measurement points which realize the same function or similar functions are consistent, all terminals in the same terminal row are automatically numbered in sequence, and the spare margin is 25%. The output of this step is the Excel table shown in FIG. 3. The schematic generated by this step is shown in fig. 5.

4. The individual circuit breaker functions and rated currents in the 220V ac power distribution module are input into a computer human machine interface. The connection mode and the function description of each breaker are determined by the 'breaker function'; the rated current of each breaker is determined by the rated current; all circuit breaker numbers are automatic numbers. The circuit breakers used in the 220V ac power distribution module in this example are all bipolar circuit breakers, including a main loop skip circuit breaker, a standby circuit breaker, a PLC rack power supply circuit breaker, a control cabinet 24V dc module power supply circuit breaker, a unit state detection system power supply circuit breaker, a strip power supply circuit breaker, and the like, as shown in fig. 6.

5. And inputting the model and rated current of each power supply in the 220V-24V direct current power supply module into a computer human-computer interface. The wiring mode of the direct current power supply is determined by the power supply model; the wiring form of the direct current power supply is determined by the rated current; the power supply number and the redundant module number are both automatic numbers. In this example, each power supply of the 220V-24V dc power supply module is a dual-mode redundant power supply with an alarm function, as shown in fig. 7.

6. The function, model and contact function of each relay in the relay module are input into the human-computer interface. The main function and the contact form of the relay are determined by the relay function; the type of the relay is determined by the relay type; the contact function of each relay is determined by the contact function, and the field passive contact can be automatically connected; all relay numbers are automatic numbers. The relays used in the relay module in this example are all safety relays, including an interlock parking relay, an electrical isolation relay, a field device control isolation relay, an alarm control relay, a backup relay, and the like, as shown in fig. 8a-8 b.

7. And inputting the name, the function and the rated current of each terminal in the 24V direct current power distribution module into a human-computer interface. Determining the name of the equipment connected with the terminal according to the terminal name; the type of equipment connected with the terminal is determined by the terminal function; the rated current of the terminal is determined by the rated current; the terminal row numbers and the terminal numbers of all the terminals are automatic numbers, and the spare allowance is 25%. The terminals used in the 24V dc power distribution module in this example are both a positive pole disconnecting link terminal and a negative pole common terminal with a rated current of 3A, and include a PLC terminal board power supply terminal, a field device power supply terminal, an electrical isolation relay power supply terminal, a switch power supply terminal, a backup terminal, and the like.

8. And automatically generating each content of the EXCEL form under the EECONE platform according to the measuring point list and each design parameter in the human-computer interface of the computer, as shown in FIG. 3.

9. Calling the preset EPLAN macro file shown in FIG. 4 from the EXCEL form under the EECONE platform shown in FIG. 3, and generating the design drawing of the EPLAN format of the required control system, as shown in FIG. 5, FIG. 6, FIG. 7, and FIGS. 8a-8 b.

The method for generating the design drawing in the EPLAN format according to the content of the EXCEL form is realized by adopting the prior EECONE module, and comprises the following steps:

obtaining page names and page descriptions of the EPLAN design drawing according to the measuring point categories in the measuring point list; a page includes macros of a station category; and mapping the number, the associated connection and the like of a certain measuring point class in the EXCEL table to the preset attributes of each macro in the corresponding EPLAN design drawing.

10. Generating a list required by a user of the compressor control system according to the design drawing:

and according to the automatically generated design drawing of the EPLAN format of the control system, sequentially listing the equipment bill of materials, the component summary list, the terminal arrangement overview list and the wiring list required by the user through a preset list format.

Claims (7)

1. The method for automatically generating the electrical schematic diagram of the compressor control system is characterized by comprising the following steps of:

importing a measuring point list of a compressor control system, and receiving input compressor control system design parameter information;

generating an EXCEL form according to the content of the measuring point list and the input design parameter information;

generating a design drawing in an EPLAN format according to the contents of the EXCEL form;

the method for generating the EXCEL form according to the content of the measuring point list and the input design parameter information comprises the following steps:

1) allocating EXCEL tables according to the type of the design parameter information, wherein each table comprises one type of design parameter information;

2) mapping a certain type of design parameter information and the corresponding content thereof in the measuring point list into cells of a corresponding table;

the mapping to the cells of each form header according to the design parameter information and the corresponding content in the measuring point list specifically comprises the following steps:

1) distributing preset information of a certain type of measuring points into table head cells corresponding to the EXCEL table;

2) distributing item numbers and control cabinet sequence numbers in the measuring point list to page attribute cells corresponding to the macro names of the tables;

3) generating macro names of all tables according to the measuring point list and the design parameter information, and sequentially listing the macro names in the first-column cells under the corresponding table heads of all tables;

4) distributing the coordinates of each macro in the design drawing to the position cell corresponding to the macro;

5) distributing each loop position number and loop name in the measuring point list to the macro attribute corresponding to the macro name of each table;

the macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first-column cells below the corresponding table heads of the tables:

1) classifying and sorting the loops according to the types of the measuring point lists to be used as macro names, and sequentially listing the macro names in the first-row cells below the corresponding heads;

2) taking the model of the loop safety barrier selected by the user as a macro name, and sequentially listing the macro name in the first row of cells under the corresponding header;

3) the user selects a terminal access mode, the loop names in the measuring point list are classified sometimes, the terminals in each class are sequenced and numbered, and the next step is executed; if not, executing the next step;

4) and (4) taking the variable value obtained by carrying out ASCII code inverse calculation on the difference between the initial measuring point and the ending measuring point of the shield line in the measuring point list as the macro variable content of the shield line.

2. The method for automatically generating the electrical schematic diagram of the compressor control system according to claim 1, wherein the measuring point list comprises a plurality of measuring point categories, namely AI measuring points, AO measuring points, PI measuring points, DI measuring points, DO measuring points and unit state monitoring system measuring points; the loop corresponding to each measuring point comprises a loop position number, a loop name and a loop type.

3. The method of claim 1, wherein the design parameter information comprises:

terminal board information: the serial number of the control cabinet, the terminal access mode, and the serial number and the model of the control cabinet where the PLC terminal board is located;

loop information: the type of a safety barrier, the number of a clamping piece of a unit state monitoring system and the number of a channel of the unit state monitoring system required by each loop;

information of the alternating current power distribution module: each breaker is connected with an object and rated current;

information of a direct current power distribution module: the model and rated current of each power supply;

information of the relay module: a connection object of a relay and a contact connection object;

information of the direct current power distribution module: each terminal name, a terminal connection object, and a rated current.

4. The method for automatically generating the electrical schematic diagram of the compressor control system according to claim 1, wherein the macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first list of cells below the corresponding table heads of the tables:

the circuit breaker connection objects selected by a user are used as macro names and are sequentially listed in the first-row cells under the corresponding heads; and distributing each rated current input by a user into the macro attribute corresponding to the model of the loop safety barrier.

5. The method for automatically generating the electrical schematic diagram of the compressor control system according to claim 1, wherein the macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first list of cells below the corresponding table heads of the tables:

the types of the power supplies selected by the user are used as macro names and are sequentially listed in the first row of cells under the corresponding header; and distributing each rated current input by a user into the macro attribute corresponding to the model of the loop safety barrier.

6. The method for automatically generating the electrical schematic diagram of the compressor control system according to claim 1, wherein the macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first list of cells below the corresponding table heads of the tables:

according to the connection object of the relay selected by the user as a macro name, sequentially listing the macro name in the first row of cells under the corresponding header; and distributing each contact connection object input by a user into the macro attribute corresponding to the model of the circuit safety barrier.

7. The method for automatically generating the electrical schematic diagram of the compressor control system according to claim 1, wherein the macro names of the tables are generated according to the measuring point list and the design parameter information, and the macro names are specifically listed in the first list of cells below the corresponding table heads of the tables:

combining each terminal name and the terminal connecting object selected by a user to be used as a macro name, and sequentially listing the macro names in the first-column cells under the corresponding header; and distributing each rated current input by a user into the macro attribute corresponding to the model of the loop safety barrier.

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