CN113268966B - Automatic generation method for cable inventory of automatic control system - Google Patents
Automatic generation method for cable inventory of automatic control system Download PDFInfo
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Abstract
The invention provides an automatic generation method of a cable inventory of an automatic control system, which comprises the following steps: compiling an auxiliary table in an Excel form; compiling a cable inventory through compiling formulas and functions according to an auxiliary table, wherein the auxiliary table comprises the following contents: instrument serial number, mounted position, auxiliary variable, instrument type and instrument code number, the content of cable list includes: the measuring point description comprises a cable terminal point and an instrument type, wherein the instrument type corresponds to an instrument code number, the IO point type, the cable specification model and the cable pipe, the instrument position number corresponds to the cable number, the measuring point description comprises the instrument terminal point and the instrument type, the instrument number and the installation position are used as input quantities, and other contents with corresponding relations utilize auxiliary variables, the input quantities and the corresponding relations, and calculation is carried out by compiling formulas and functions in an Excel table. The accuracy and the design quality are improved, and the workload is reduced.
Description
Technical Field
The invention relates to the field of automatic control design, in particular to a design method for a cable inventory of an automatic control system, and particularly relates to an automatic generation method for the cable inventory of the automatic control system.
Background
The cable inventory is a common form in the field of automatic control, and is used as a basis for construction paying-off and construction guidance. The cable is mainly composed of instrument position numbers, measurement point descriptions, IO point types, cable numbers, cable specification models, cable starting points, cable end points, lengths and cable pipes. The cable number is a mark for identifying the cable, the numbers of all the cables in a project cannot be repeated, and the cable number has certain meanings and rules, so that the cable number is convenient to design and construct. Common measuring points of a heat (cold) supply project comprise pressure, temperature, flow, liquid level, a regulating valve, an electric valve, a water pump and the like, common measuring points comprise DI, DO, AI, AO, RTD and the like, and common control cables comprise polyvinyl chloride insulated control cables: ZR-KVVP, ZR-KVV, and the like.
At present, the method for designers to compile cable inventory is to manually copy, paste and edit in CAD or Excel, and input or modify the contents of instrument position number, measurement point description, IO point type, cable number, cable specification model, cable starting point, cable ending point, length, cable pipe and the like one by one. Some problems with the existing manual programming methods are found based on the authors' experience over many years in the design field. One is the workload problem. The workload of cable inventory compilation has a positive correlation with IO points. The more IO points, the greater the workload of compiling the cable inventory. For a small project, such as a heat exchange station, if the process and the automatic control system of the heat exchange station are designed conventionally, the total number of IO points is mostly within 100 points, and the workload of manually compiling a cable list for the project is not large. However, for large-scale projects such as heat supply plants and refrigeration stations, the total number of IO points can reach thousands or even thousands of points, cable inventory can reach thousands of lines, and the workload of manually compiling the cable inventory for such projects is huge. And the second is the repeatability problem of cable inventory. Because the small project and the large project measuring point are similar in types, most contents in the cable inventory are similar and repetitive. Thirdly, the accuracy problem of cable inventory. Although the cable inventory contents of the larger project and the small project are similar, due to the large workload of manual programming, various errors such as wrong cable numbers, wrong cable specification and model selection, wrong cable pipes and the like often occur in the cable inventory due to subjective reasons of designers. These errors are errors that designers often make, and are difficult to avoid, although they may be discovered during inspection of drawings or construction, or even if not discovered, have little impact on construction line deployment. However, the drawing accuracy represents the quality of drawing, and in order to avoid errors caused by subjective reasons of designers, improve the design quality, reduce the workload of repeated work of the designers and improve the working efficiency of the designers, an automatic cable inventory compiling method is urgently needed to replace the existing manual cable inventory compiling method.
Disclosure of Invention
The invention aims to research an automatic cable inventory compiling method according to the defects of the prior art, provides an automatic generation method of an automatic control system cable inventory, can automatically calculate and has high accuracy, and by adopting the method, the accuracy of the cable inventory can be greatly improved while the repeated work of designers is reduced, so that the method has better application prospect and application value.
The purpose of the invention is realized by the following ways:
an automatic generation method for a cable inventory of an automatic control system comprises the following steps:
and 2, compiling the cable inventory according to the auxiliary table by compiling formulas and functions.
Preferably, the auxiliary table content includes: instrument number, mounting location, auxiliary variable, instrument type, and instrument code.
Preferably, the meter numbers are consecutive or non-consecutive, and an appropriate numbering rule of the meter numbers is selected according to the characteristics of the project.
Preferably, the contents of the cable inventory include: instrument position number, measurement point description, IO point type, cable number, cable specification model, cable starting point, cable terminal point, cable length and cable pipe.
Preferably, the meter type corresponds to the meter code number, the IO point type, the cable specification type, and the cable tube, the meter position number corresponds to the cable number, the measurement point description is composed of the cable end point and the meter type, the meter number and the installation position are used as input quantities, and other contents having a correspondence are calculated by writing a formula and a function in an Excel table by using the auxiliary variable, the input quantity, and the correspondence.
Preferably, the step 1 comprises:
and step 15, inputting the installation position.
Preferably, the step 2 comprises:
step 26, obtaining the cable terminal through an Excel formula according to the corresponding relation between the cable terminal and the installation position and the instrument type;
step 27, estimating the length of the cable length according to the process plan, the cable route and the position of the cable starting point;
and step 28, judging the cable specification model through an IF function of Excel according to the corresponding relation between the cable pipe and the cable specification model, thereby obtaining the cable pipe.
Preferably, the step 22 may further include:
and step 22', judging the value of the auxiliary variable through an IF function of Excel according to the corresponding relation between the measuring point description and the auxiliary variable, thereby obtaining the measuring point description.
Preferably, the starting point of the cable is a control cabinet or an instrument power distribution cabinet.
Preferably, the control cabinet is a PLC cabinet or a DCS cabinet.
The invention has the beneficial effects that:
according to the method and the steps, various formulas and functions of the auxiliary form and the cable inventory are compiled in the Excel form, and when the method and the device are used, the instrument number, the installation position and the cable length are input, so that a complete cable inventory can be automatically generated, the compiling workload of the cable inventory is greatly reduced, the accuracy is improved, the existing method for manually compiling the cable inventory is replaced, the error caused by the subjective reason of a designer can be avoided, the design quality is improved, the workload of repeated work of the designer is reduced, and the working efficiency of the designer is improved.
The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.
Brief description of the drawings
FIG. 1 is a screenshot of an auxiliary form and cable inventory according to an embodiment of the invention.
Detailed Description
The invention discloses an automatic generation method of a cable inventory of an automatic control system, which comprises the following steps:
and 2, compiling a cable inventory according to the auxiliary table by compiling a formula and a function.
Wherein the auxiliary table content comprises: instrument number, mounting location, auxiliary variable, instrument type, and instrument code.
Wherein, the meter number is continuous or discontinuous, and the proper numbering rule of the meter number is selected according to the characteristics of the project.
Wherein, the content of cable list includes: instrument position number, measurement point description, IO point type, cable number, cable specification model, cable starting point, cable terminal point, cable length and cable pipe.
The instrument type corresponds to an instrument code, an IO point type, a cable specification model and a cable pipe, the instrument position number corresponds to a cable number, and the measurement point description comprises a cable terminal point and the instrument type. The instrument types of the heating and cooling project mainly comprise pressure, temperature, flow, liquid level, regulating valves, electric valves, pumps and the like. The instrument number and the installation position are used as input quantities, and other contents with corresponding relations are calculated by compiling formulas and functions in an Excel table by using auxiliary variables, the input quantities or the corresponding relations.
Wherein, step 1 includes:
Wherein, step 2 includes:
24, obtaining a cable number through an Excel formula according to the corresponding relation between the cable number and the instrument number; the cable number is a mark for identifying the cable, and the numbers of all the cables in one project cannot be repeated.
step 26, obtaining a cable terminal point through an Excel formula according to the corresponding relation between the cable terminal point and the installation position and the instrument type;
step 27, estimating the length of the cable length according to the process plan, the cable route and the position of the cable starting point;
and 28, judging the specification and model of the cable according to the corresponding relation between the cable pipe and the specification and model of the cable through an IF function of Excel, and obtaining the cable pipe.
Wherein, step 22 can also be replaced by:
and step 22', judging the value of the auxiliary variable through the IF function of Excel according to the corresponding relation between the measurement point description and the auxiliary variable, thereby obtaining the measurement point description.
The cable starting point is usually a control cabinet or an instrument power distribution cabinet, and in this embodiment, the control cabinet is a PLC cabinet or a DCS cabinet.
Referring to fig. 1, a screenshot of an auxiliary form and a cable inventory generated in a specific implementation process of this embodiment is shown, where the process includes:
1) And compiling an auxiliary table. The supplementary table content includes: instrument number, installation position, auxiliary variable, instrument type, instrument code. The method comprises the following steps:
a. and (3) assigning auxiliary variables to each type of instrument according to IO points of the instruments: pressure: 1, temperature: 2, flow rate: 3. 30, liquid level: 5, adjusting a valve: 6. 60, electrically operated valve: 21. 211, 212, 213, 214, 215, 216, pump frequency conversion: 22. 221, 222, 223, 224, 225, 226, 227, 228;
b. meter type = IF (auxiliary variable =1, "pressure", IF (auxiliary variable =2, "temperature", IF (auxiliary variable =3, "flow", IF (auxiliary variable =5, "liquid level", IF (auxiliary variable =6, "regulating valve", IF (auxiliary variable =21, "electric valve", IF (auxiliary variable =22, "pump frequency"))))));
c. the meter number 5= IF (auxiliary variable =1, "PT", IF (auxiliary variable =2, "TE", IF auxiliary variable =3, "FT", IF (auxiliary variable =5, "LT", IF (auxiliary variable =6, "TV", IF (auxiliary variable =21, "FZV", IF (auxiliary variable =211, "MST", IF (auxiliary variable =212, "MSS", IF (auxiliary variable =213, "ZA", IF (auxiliary variable =214, "ZB", IF (auxiliary variable =215, "ZC", IF (auxiliary variable =216, "ZD", IF (auxiliary variable =221, "MST", IF (auxiliary variable =222, "MSS", IF (auxiliary variable =223, "ZA", IF (auxiliary variable =224, "ZB"), IF (auxiliary variable =225, "ZC", IF (auxiliary variable =226, "SSP"), IF (auxiliary variable =228, "ET"))))))))))))))))))))));
d. inputting a meter number;
e. the mounting position is input.
2) And compiling a cable list. The cable inventory content comprises: the cable comprises an instrument position number, a measurement point description, an IO point type, a cable number, a cable specification model, a cable starting point, a cable terminal point, a cable length and a cable pipe;
a. instrument bit number = instrument code number & "-" & instrument number;
b. for temperature, pressure, flow, level, regulating valve, station description = installation position & meter type. For the electric valve, the measurement point specification = IF (auxiliary variable =21, mounting position & instrument type, IF (auxiliary variable =211, "valve open control", IF (auxiliary variable =212, "valve closed control", IF (auxiliary variable =213, "valve open limit", IF (auxiliary variable =214, "valve Guan Xianwei", IF (auxiliary variable =215, "failure", IF (auxiliary variable =216, "remote/local"))))))))). For pump frequency conversion, measurement point specification = IF (auxiliary variable =22, installation location & instrument type, IF (auxiliary variable =221, "start", IF (auxiliary variable =222, "stop", IF (auxiliary variable =223, "run", IF (auxiliary variable =224, "fault", IF (auxiliary variable =225, "remote/local", IF (auxiliary variable =226, "frequency conversion given", IF (auxiliary variable =227, "frequency conversion feedback", IF (auxiliary variable =228, "motor current")))))))));
c. IO point type = IF (OR (auxiliary variable =1, auxiliary variable =5, auxiliary variable =227, auxiliary variable = 228), "AI", IF (auxiliary variable =226, "AO", IF (auxiliary variable =60, "AI/AO", IF (auxiliary variable =2, "RTD", IF (OR (auxiliary variable =3, auxiliary variable = 6), "power", IF (auxiliary variable =30, "RS485", IF (auxiliary variable =21, "power", IF (OR (auxiliary variable =211, auxiliary variable =212, auxiliary variable =221, auxiliary variable = 222), "DO"), IF (OR (auxiliary variable =213, auxiliary variable =214, auxiliary variable =215, auxiliary variable =216, auxiliary variable =223, auxiliary variable =224, auxiliary variable = 225), "DI"))))))))));
d. cable number = instrument number & C, instrument number & P, instrument number & a, instrument number & B, and the like;
e. cable specification model = IF (OR (auxiliary variable =1, auxiliary variable =30, auxiliary variable = 5), "ZR-KVVP3x1.0", IF (auxiliary variable =2, "ZR-KVVP 4x1.0", IF (auxiliary variable =60, "ZR-KVVP 5x1.0", IF (AND (auxiliary variable =226, auxiliary variable =227, auxiliary variable = 228), "ZR-KVVP 7x1.0", IF (OR (auxiliary variable =3, auxiliary variable = 6), "ZR-KVVP 3x2.5", IF (auxiliary variable =21, "ZR-KVVP 5x2.5", IF (AND (auxiliary variable =211, auxiliary variable = 212), "ZR-KVV 5x1.0", IF (AND (auxiliary variable =221, auxiliary variable = 222), "ZR-KVV 5x1.0", IF (AND (auxiliary variable =223, auxiliary variable =224, auxiliary variable = 225), "ZR-KVV 7x1.0", IF (AND (auxiliary variable =213, auxiliary variable =214, auxiliary variable =215, auxiliary variable = 216), "ZR-KVV 10x1.0")))))))))));
f. the cable starting point = a control cabinet PLC cabinet, a DCS cabinet and the like or an instrument power distribution cabinet;
g. cable termination = meter installation position, meter installation position & meter type & "switch board".
h. Estimating the length of the cable according to a process plan, a cable route and the position of a control cabinet or an instrument power distribution cabinet;
i. cable tube = IF (cable specification model = "ZR-KVVP 10 × 1.0", SC25, SC 20)).
For example, for a pressure transmitter, the gauge number is 1101, the installation location is the boiler feed pipe, its auxiliary variable is 1, the gauge type is pressure, and the gauge number is PT. Then the contents of the cable inventory are respectively as follows: the instrument position number: PT-1101, description of measurement points: boiler feed pipe pressure, IO point type: AI, cable number: 1101C, cable specification model: ZR-KVVP3x1.0, cable origin: control cabinet, cable terminal: boiler feed pipe, cable length: according to the process plan, the cable route and the control cabinet position estimation, the cable pipe is as follows: SC20. Except that the instrument number, the installation position and the cable length are manually input and modified by designers, other contents can be automatically generated.
The automatic generation method of the cable inventory of the automatic control system is described above by taking common pressure, temperature, flow, liquid level, regulating valve, electric valve, pump and the like as examples, wherein the specification and model of the cable can be selected according to different project requirements. For other instruments, such as flow switches, electromagnetic valves, fans, boilers, coolers, etc., which are not mentioned in the present invention, the cable inventory making method can refer to the method.
The technical solutions provided by the embodiments of the present invention are described in detail above, and the principles and embodiments of the present invention are explained herein by using specific examples, and the descriptions of the embodiments are only used to help understanding the principles of the embodiments of the present invention; meanwhile, a person skilled in the art may change the embodiments and the application scope according to the embodiments of the present invention, and in summary, the content of the present description should not be construed as limiting the present invention.
Claims (3)
1. An automatic generation method of a cable inventory of an automatic control system is characterized by comprising the following steps:
step 1, compiling an auxiliary table in an Excel form;
step 2, compiling the cable inventory through compiling formulas and functions according to the auxiliary table;
wherein the auxiliary table content comprises: instrument number, installation position, auxiliary variable, instrument type and instrument code;
wherein, the meter numbers are continuous or discontinuous, and a proper numbering rule of the meter numbers is selected according to the project characteristics;
wherein, the content of the cable inventory includes: the cable comprises an instrument position number, a measurement point description, an IO point type, a cable number, a cable specification model, a cable starting point, a cable terminal point, a cable length and a cable pipe;
the instrument type corresponds to the instrument code number, the IO point type, the cable specification type and the cable pipe, the instrument position number corresponds to the cable number, the measurement point description consists of the cable terminal point and the instrument type, and the instrument number and the installation position are used as input quantity;
wherein the step 1 comprises:
step 11, endowing each type of instrument with the auxiliary variable according to the IO point;
step 12, judging the value of the auxiliary variable through an IF function of Excel according to the corresponding relation between the instrument type and the auxiliary variable, thereby obtaining the instrument type;
step 13, judging the value of the auxiliary variable through an IF function of Excel according to the corresponding relation between the instrument code and the auxiliary variable so as to obtain the instrument code;
step 14, inputting the number of the meter;
step 15, inputting the installation position,
wherein the step 2 comprises:
step 21, obtaining the instrument position number through an Excel formula according to the corresponding relation among the instrument position number, the instrument code number and the instrument number;
step 22, obtaining the measuring point description through an Excel formula according to the corresponding relation between the measuring point description and the installation position and the instrument type; or judging the value of the auxiliary variable through an IF function of Excel according to the corresponding relation between the measuring point description and the auxiliary variable, thereby obtaining the measuring point description
Step 23, judging the value of the auxiliary variable through an IF function of Excel according to the corresponding relation between the IO point type and the auxiliary variable, thereby obtaining the IO point type;
step 24, obtaining the cable number through an Excel formula according to the corresponding relation between the cable number and the instrument number; the cable number is a mark for identifying the cable, and the numbers of all the cables in one project cannot be repeated;
step 25, judging the value of the auxiliary variable through an IF function of Excel according to the corresponding relation between the cable specification model and the auxiliary variable so as to obtain the cable specification model;
step 26, obtaining the cable terminal through an Excel formula according to the corresponding relation between the cable terminal and the installation position and the instrument type;
step 27, estimating the length of the cable length according to the process plan, the cable route and the position of the cable starting point;
and step 28, judging the specification and model of the cable through an IF function of Excel according to the corresponding relation between the cable pipe and the specification and model of the cable, and obtaining the cable pipe.
2. The method according to claim 1, wherein the cable is selected from a control cabinet and an instrument distribution cabinet.
3. The method of claim 2, wherein the control cabinet is a PLC cabinet or a DCS cabinet.
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