JP2011158010A - Simulation program and simulation device of gas pipeline - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To grasp a gas suppliable amount to each demand area without technical knowledge. <P>SOLUTION: The device comprises a laying database 5 for storing laying information including a laying state of gas pipeline from a gas supply source to each demand area, an input part 2 for inputting a transport gas pressure of a supply source and a required gas pressure of a demand area as a pressure parameter and either of a gas supply/demand amount in each demand area and a diameter of gas pipeline as a selective parameter, and a simulator 7 for calculating the gas supply/demand amount or the diameter of the gas pipeline which are not inputted in the input part 2 on the basis of the laying information stored in the laying database 5 and the pressure parameter and selective parameter inputted in the input part 2. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a gas pipeline simulation program and a simulation apparatus for simulating the amount of gas that can be supplied to each demand area in a gas pipeline (conduit) for transporting natural gas or the like.

  Gas pipelines are used as means for transporting from natural gas storage areas, mining areas, or LNG bases to demand / consumption areas (see, for example, Patent Document 1). In other words, a gas pipeline is laid from the supplier to each demand area, and the supplier supplies the natural gas with a high pressure (transport gas pressure) and transports it through the gas pipeline to supply natural gas to each demand area. Therefore, it is necessary to send natural gas of a predetermined amount and a predetermined pressure to each demand area. For this reason, when supplying natural gas, how much natural gas can be supplied to each demand area by applying how much pressure is supplied by the supplier, or a predetermined amount of natural gas can be supplied to each demand area. In order to send gas, it is necessary to appropriately calculate and predict (assum) how much the diameter of the gas pipeline from the supplier is necessary.

JP 2003-343798 A

  By the way, in the calculation and prediction of the supply amount and diameter as described above, the fluid pipeline calculation such as the flow rate and the pressure loss and the material dynamics such as the stress are taken into consideration in consideration of the laid state of the gas pipeline. Calculations must be performed and technical and specialized knowledge and experience are required. Therefore, it is necessary to perform various calculations by a person in charge who has such technical and specialized knowledge, and even such a person in charge requires a lot of labor and time for the calculation. . In particular, when the laying state of the gas pipeline is complicated, for example, when natural gas is supplied from a single supply source to a plurality of demand areas, the calculation becomes complicated and appropriate calculation becomes difficult.

  Moreover, in actual operations, each demand area is changed so that appropriate supply volume and ultimate pressure can be obtained in the entire supply system (each demand area) while changing the natural gas demand and necessary pressure in each demand area. Demand volume, required pressure, supply pressure at the supplier, or gas pipeline diameter. That is, the calculation and prediction as described above must be repeated, which requires a lot of labor and time, and makes it more difficult to perform proper calculation and prediction.

  Accordingly, the present invention provides a gas pipeline simulation program and a simulation device that can grasp the amount of gas that can be supplied to each demand area on the gas pipeline without having technical knowledge. With the goal.

  In order to achieve the above object, according to the first aspect of the present invention, there is provided a laying information storage means for storing laying information including a laying state of a gas pipeline from a gas supply source to each demand place, and the supply source. Parameter receiving means for receiving the transport gas pressure and the required gas pressure of the demand area as pressure parameters, and accepting one of the gas supply / demand amount (gas demand amount) or the diameter of the gas pipeline in each demand area as a selection parameter; Based on the laying information stored in the laying information storage means, the pressure parameter accepted by the parameter accepting means and the selection parameter, the gas supply / demand amount (gas supplyable amount) or gas pipe not accepted by the parameter accepting means To function as a calculation means for calculating the line diameter (required pipe diameter) Is a simulation program of the gas pipeline.

  According to the present invention, for example, when the supply gas pressure of the supplier, the required gas pressure at each demand area and the gas demand amount are input (designated) via the parameter receiving means, the input parameters are satisfied by the calculating means. The required pipe diameter of the gas pipeline is calculated. Also, for example, when the transport gas pressure of the supplier, the required gas pressure at each demand area, and the diameter of the gas pipeline are input via the parameter receiving means, the gas to each demand area that satisfies the input parameters is calculated by the calculation means. The supplyable amount is calculated.

  According to a second aspect of the present invention, in the simulation program according to the first aspect, the calculation means is configured to calculate the gas supply / demand amount or the gas pipeline based on an actual measurement value of pressure loss when the gas is transported through the gas pipeline. The diameter is calculated.

  According to a third aspect of the present invention, in the simulation program according to the first or second aspect, the parameter accepting unit accepts a length of the gas pipeline as a line length parameter, and the calculating unit is the parameter accepting unit. Based on the accepted line length parameter, the gas supply / demand amount or the diameter of the gas pipeline is calculated.

  According to this invention, when the length of the gas pipeline is input via the parameter receiving means, the amount of gas that can be supplied to each demand area or the required pipe diameter of the gas pipeline is calculated by the calculating means based on the input length. Calculated.

  The invention described in claim 4 is a laying information storage means for storing laying information including a laying state of a gas pipeline from a gas supply source to each demand place, the transport gas pressure of the supply source, and the necessity of the demand place Input means for inputting the gas pressure as a pressure parameter and inputting one of the gas supply / demand amount (gas demand amount) or the diameter of the gas pipeline in each demand area as a selection parameter; and the laying stored in the laying information storage means Based on the information, the pressure parameter input by the input means, and the selection parameter, the gas supply / demand amount (gas supply possible amount) or the gas pipeline diameter (required pipe diameter) not input by the input means is calculated. And a gas pipeline simulation apparatus.

  According to the present invention, for example, when the transportation gas pressure of the supplier, the required gas pressure at each demand area and the gas demand amount are input by the input means, the required pipe diameter of the gas pipeline that satisfies the input parameters by the calculation means. Is calculated. Further, when the input means inputs, for example, the supply gas pressure of the supplier, the required gas pressure of each demand area, and the diameter of the gas pipeline, the amount of gas that can be supplied to each demand area that satisfies the input parameters is calculated by the calculation means. Is calculated.

  According to the first and fourth aspects of the present invention, the gas supply to each demand area based on the laying state of the gas pipeline, etc. by inputting the transport gas pressure of the supply source, the necessary gas pressure of each demand area, etc. The possible amount or the diameter of the gas pipeline is calculated. That is, the gas supply capacity to each demand area corresponding to the required gas pressure in each demand area, and the gas pipeline diameter corresponding to the gas demand amount in each demand area are calculated. For this reason, even if you do not have technical and specialized knowledge and experience, you can know the amount of gas that can be supplied to each demand area, and even if the laying state of the gas pipeline is complicated, Easily and appropriately know the amount of gas that can be supplied to each demand area.

  Furthermore, even when determining the optimum conditions so that an appropriate gas supply amount can be obtained in the entire supply system while changing the conditions such as the transportation gas pressure of the supplier and the required gas pressure at each demand point, the conditions must be met. The gas supply capacity to each demand area is sequentially calculated only by inputting sequentially. Similarly, by sequentially inputting conditions such as required gas pressure and gas demand in each demand area, the diameter of the gas pipeline necessary to satisfy the conditions is sequentially calculated. For this reason, it becomes possible to appropriately and easily examine and select the gas supply amount to each demand area and the diameter of the gas pipeline in the entire supply system.

  According to the second aspect of the present invention, since the amount of gas that can be supplied to each demand area or the diameter of the gas pipeline is calculated based on the actual measurement value of the pressure loss, a more appropriate calculation that matches the actual pressure loss. The result can be obtained.

  According to the third aspect of the present invention, since the gas supplyable amount to each demand area or the diameter of the gas pipeline is calculated based on the input length of the gas pipeline, the length of the gas pipeline is changed. In such a case, the amount of gas that can be supplied to each demand area can be obtained appropriately and easily.

1 is a schematic block diagram showing a gas pipeline simulation apparatus according to an embodiment of the present invention. It is a figure which shows the example of the calculation result sheet | seat memorize | stored in the installation database of the apparatus of FIG. It is a figure which shows the example of the calculation sheet memorize | stored in the laying database of the apparatus of FIG. It is a figure which shows the continuation of FIG. It is a flowchart which shows the processing flow of the simulator of the apparatus of FIG.

  The present invention will be described below based on the illustrated embodiments.

  FIG. 1 is a schematic block diagram showing a gas pipeline simulation apparatus (hereinafter referred to as “simulation apparatus”) 1 according to an embodiment of the present invention. This simulation device 1 is a device for simulating gas supplyable amount (gas supply / demand amount) to each demand place in a gas pipeline for transporting natural gas, and is composed of a general-purpose computer, mainly comprising an input unit (input means) ) 2, a display unit 3, a storage unit 4, a laying database (laying information storage means) 5, a pipe material database 6, a simulator 7, and a central processing unit 8 that controls these.

  The input unit 2 inputs pressure parameters, selection parameters, and the like, which will be described later, and includes a keyboard and a mouse. Various parameters input by the input unit 2 are accepted (taken in) into the simulator 7 by a parameter task 71 described later. The display unit 3 displays input data, parameters, calculation results, and the like in the simulator 7 and includes an LCD (liquid crystal display). The storage unit 4 is a memory that temporarily stores calculation results by the simulator 7.

  The laying database 5 is a database that stores laying information including the laying state of the gas pipeline from the gas supply source to each demand place. Specifically, the route (trajectory) and burial depth of the gas pipeline from one supply source (base) to each demand area are stored for each supply system. Further, when the simulator 7 has already input the length, pipe diameter, etc. of the gas pipeline between the demand areas, the laying information is also stored. That is, before the simulation by the simulator 7, the gas pipeline route and the embedding depth are stored at a minimum, and when initial values such as the length and the pipe diameter of the gas pipeline are set, Is stored. After the simulation by the simulator 7, the gas pipeline route and embedment depth, the input gas pipeline length and pipe diameter, and the calculation result gas pipe diameter and each demand area The amount of gas that can be supplied to is stored. More specifically, a calculation result sheet 51 as shown in FIG. 2 and a calculation sheet 52 as shown in FIGS. 3 and 4 are stored.

  The pipe material database 6 is a database that stores specification information regarding the pipe material of the gas pipeline. Specifically, the material of the pipe material, the tensile strength, the outer diameter with respect to each nominal diameter, the thickness, the inner diameter, and the like are stored.

  The simulator 7 is a program for simulating the gas supply possible amount to each demand place on the gas pipeline. As shown in FIG. 5, the simulator 7 mainly includes a parameter task (parameter receiving means) 71 and a calculation task (calculation means). 72. The parameter task 71 is a program that accepts various parameters input by the input unit 2, and can accept various parameters by the cells IC <b> 1 to IC <b> 7 on the calculation result sheet 51. Here, the following parameters are included as accepted parameters.

"Demand parameter (selection parameter)"
The gas demand amount (gas supply / demand amount) at each demand place P3, P5..., And is accepted by the supply / demand cell C1 at each demand place P3, P5. In addition, the supply / demand cell C1 is a cell (area) that accepts a demand parameter and displays and stores a gas supplyable amount to each demand area as a calculation result, as will be described later.

"Pressure parameters"
The transport gas pressure (feed pressure) of the supply source P1 and the required gas pressure in each of the demand areas P3, P5... Are received by the pressure cell C2 on the supply source P1 and each of the demand areas P3, P5. The pressure cell C2 is a cell that receives a pressure parameter and displays and stores an ultimate gas pressure that is a calculation result, as will be described later.

"Line length parameter"
The length of the gas pipeline from the supply source P1 to the first demand place P3 (= P2) and the length of the gas pipeline between the demand places P3, P5..., And the line length cell C3 on each gas pipeline. Accepted.

“Line Diameter Parameter (Selection Parameter)”
The diameter (nominal diameter) of the gas pipeline from the supply source P1 to the first demand place P3, and the diameter of the gas pipeline between the demand places P3, P5... . The line diameter cell C4 is a cell that accepts a line diameter parameter and displays and stores the diameter of the gas pipeline as a calculation result, as will be described later.

"Load factor parameter"
This is the gas load factor at the supply source P1 and each of the demand areas P3, P5... And is accepted by the load factor cell C5 on the supply source P1 and each of the demand areas P3, P5.

"Minimum ultimate pressure parameter"
This is the lowest pressure that is the minimum required gas pressure in the demand area P14 farthest from the supply source P1, and is accepted by the lowest pressure cell C6 on the demand area P14.

`` Open / close valve parameters ''
This parameter indicates the open / close state of the open / close valve on the gas pipeline, and is accepted by the open / close valve cell C7 located upstream of each of the demand areas P3, P5. That is, when a certain on-off valve is in the “closed” state to stop the gas flow, “closed” (“×”) is accepted by the on-off valve cell C7 of each corresponding demand place P3, P5.

  The calculation task 72 can supply gas to the demand areas P3, P5... That are not accepted by the parameter task 71 based on the laying information stored in the laying database 5 and various parameters accepted by the parameter task 71. This is a program that calculates the amount (gas supply and demand), the required diameter of the gas pipeline, etc., and mainly calculates the following items.

`` Achieved gas pressure ''
This is the ultimate gas pressure at each of the demand areas P3, P5..., And is calculated when the demand amount parameter is accepted by the parameter task 71 and the required gas pressure at each of the demand areas P3, P5. And is calculated as follows. That is, as shown in FIG. 3, the arrival gas pressure on the arrival side which is the nearest demand point is calculated based on the gas pressure on the delivery side in order from the supply source P1 according to the laying state (route) of the gas pipeline. Specifically, the gas pressure (attainment gas pressure) at the first demand place P3 when the total supply amount of gas is transported from the supply source P1 to the first demand place P3 (= P2) is calculated. Next, the arrival at the second demand place P5 when the gas of the total demand amount after the second demand place P5 is transported from the first demand place P3 to the second demand place P5 (= P4). The ultimate gas pressure is calculated sequentially for each section, such as calculating the gas pressure.

  Here, the calculation of the ultimate gas pressure is known based on the gas pressure on the delivery side, the length of the gas pipeline in the target section, the inner diameter of the gas pipeline in the target section, the gas flow rate flowing through the target section, the gas specific gravity, and the flow coefficient. Further, calculation is performed based on the actual measurement value of the pressure loss when natural gas is transported through the gas pipeline. In other words, the ratio or difference between the ultimate gas pressure based only on the calculation formula and the actual gas pressure based on the actual measurement value is used as the actual measurement correction value, and the ultimate gas pressure based on the calculation formula alone is corrected with the actual measurement correction value to calculate the ultimate gas pressure. To do. Thus, since the ultimate gas pressure is based on the gas pressure on the delivery side, the length and inner diameter of the gas pipeline in the target section, the gas flow rate flowing through the target section, etc., as will be described later, the gas in each of the demand areas P3, P5. Demand amount (demand amount parameter), transport gas pressure of supply source P1 (pressure parameter), length of gas pipeline of target section, nominal diameter (line length parameter, line diameter parameter) are reached each time it is input and changed The gas pressure is calculated. The calculation result is reflected and stored in the pressure cell C2 on the calculation result sheet 51 and the “pressure information” on the calculation sheet 52.

“Gas supply capacity”
This is the amount of gas that can be supplied to each of the demand areas P3, P5, and is calculated when the parameter task 71 accepts the pressure parameter, the line diameter parameter (selection parameter), etc., and the demand quantity parameter is not accepted The calculation is performed as follows. That is, based on the installed state stored in the installed database 5 and the pressure parameter and the line diameter parameter received in the parameter task 71, it is necessary that the ultimate gas pressure at each of the demand areas P3, P5. The gas supply possible quantity in each demand place P3, P5 ... is calculated (back calculation) so that it may become gas pressure. At this time, in the same manner as the calculation in “Achieved gas pressure”, the gas pressure on the delivery side, the length of the gas pipeline in the target section, the inner diameter of the gas pipeline in the target section, the gas flow rate in the target section, the gas specific gravity, the flow Based on the coefficient, calculation is performed using a known equation, and further, calculation is performed based on an actual measurement value of pressure loss when natural gas is transported through a gas pipeline. Further, when there are a plurality of calculation results, that is, when a plurality of gas supplyable amount patterns can be calculated in each of the demand areas P3, P5,..., The calculation is made based on the priorities input and set in advance. The calculation result is reflected and stored in each supply / demand cell C1 on the calculation result sheet 51 and “demand information” on the calculation sheet 52.

"Total supply"
This is the total amount of gas required at the supply source P1, and is calculated based on the amount of gas demand and the amount of gas that can be supplied at each of the demand areas P3, P5. The calculation result is reflected and stored in the total demand / supply cell C8 on the calculation result sheet 51 and the “demand information” on the calculation sheet 52.

"Gas pipeline diameter"
The diameter (inner diameter) of the gas pipeline from the supply source P1 to the first demand area P3 and the diameter of the gas pipeline between the respective demand areas P3, P5,... ) And the like are accepted, and the line diameter parameter is not accepted, and is calculated as follows. That is, based on the laying state stored in the laying database 5 and the pressure parameter, demand parameter, etc. received in the parameter task 71, it is necessary that the ultimate gas pressure at each demand place P3, P5. The diameter of each gas pipeline is calculated (back calculation) so that the gas pressure is obtained. At this time, in the same manner as the calculation in “Achieved gas pressure”, the gas pressure on the delivery side, the length of the gas pipeline in the target section, the inner diameter of the gas pipeline in the target section, the gas flow rate in the target section, the gas specific gravity, the flow rate Based on the coefficient, calculation is performed using a known equation, and further, calculation is performed based on an actual measurement value of pressure loss when natural gas is transported through a gas pipeline. Further, when there are a plurality of calculation results, that is, when a plurality of combinations / patterns of the diameters of the gas pipelines in each section can be calculated, the calculation is performed based on the priorities input and set in advance. The calculation result is reflected and stored in each line diameter cell C4 on the calculation result sheet 51 and “pipeline information” on the calculation sheet 52.

"Gas pipeline wall thickness"
The thickness and pipe thickness of the gas pipeline in each section, and the required thickness t is calculated by the following three equations. Then, the most recent standard thickness (standardized thickness) equal to or greater than the maximum value of these calculated values is set as the thickness of the gas pipeline. The calculation result is reflected and stored in “pipeline information” on the calculation sheet 52.
f: Allowable tensile stress σ: Material tensile strength C: Corrosion allowance D ₀ : Outer diameter of gas pipeline Wf: Overload load Wt: Road surface heavy earth pressure Kf: Coefficient A depending on material of gas pipeline
Kt: Coefficient B depending on the material of the gas pipeline
P: Maximum working pressure η: Longitudinal joint efficiency

  Further, the calculation task 72 has a drawing function, and creates a graph representing the gas demand amount, the gas supply possible amount, the ultimate gas pressure, and the like in each demand place P3, P5. Specifically, as shown in FIG. 2, the transport gas pressure of the supply source P1 and the ultimate gas pressure at each of the demand areas P3, P5,... Are represented by a line graph G1, and the total supply amount of the supply source P1 and each of the demand areas P3. , P5... Is represented by a first bar graph G2, and a gas demand amount and a gas supplyable amount at each of the demand areas P3, P5... Are represented by a second bar graph G3.

  The laying database 5, the pipe material database 6, and the simulator 7 as described above constitute a gas pipeline simulation program. And the simulation by such a simulation program changes the gas demand amount in each demand place P3, P5 ..., the diameter of the gas pipeline of each section, or a new gas pipeline for a new demand place. It is executed when laying.

  Next, operations of the simulation apparatus 1 and the simulation program having such a configuration will be described. First, as shown in FIG. 5, when the simulator 7 is activated and the supply system to be simulated is designated by the input unit 2, the laying information of the corresponding gas pipeline from the laying database 5, that is, the calculation result sheet 51 and the calculation sheet 52. Is acquired and displayed on the display unit 3 (step S1). Next, at the input unit 2 as described above, the gas demand amount at each demand place P3, P5... (Step S21), the required gas pressure at each demand place P3, P5. When the length (step S23) or the nominal diameter (step S24) is input, these parameters are accepted by the parameter task 71, and the calculation task 72 is activated.

  Subsequently, based on the various parameters input as described above by the calculation task 72, the gas supply capacity to the demand areas P3, P5..., The total supply volume, or the required diameter of the gas pipeline in each section, etc. Is calculated (steps S3 and S4), and the graphs G1 to G3 as described above are drawn based on the calculation results (step S5). These calculation results and graphs G1 to G3 are reflected on the calculation result sheet 51 and the calculation sheet 52 and displayed on the display unit 3 (step S6).

  At this time, if the ultimate gas pressure in the demand area P14 farthest from the supply source P1 is less than the above-mentioned minimum ultimate pressure (minimum pressure cell C6), an alarm “insufficient ultimate pressure” is displayed on the display unit 3. The Further, when “closed” is input to the on-off valve cell C7 of the specific demand areas P3, P5,..., The total supply amount, the gas supply capacity, the ultimate gas pressure before the demand areas P3, P5,. Etc. are calculated and displayed, and the gas supply possible amount and the ultimate gas pressure after the demand areas P3, P5... Are displayed as zero.

  Subsequently, when the parameter is changed and the simulation is continued (in the case of “N” in step S7), the process returns to steps S21 to S24 and the same processing is repeated. That is, each time the demand amount P3, P5,..., The gas demand amount, the transport gas pressure of the supply source P1, the length of the gas pipeline in each section, the nominal diameter, or the like is input or changed, The amount of gas that can be supplied to P5, the required diameter of the gas pipeline in each section, and the like are calculated, and the calculation results are displayed on the display unit 3. When the simulation is terminated (in the case of “Y” in step S7), the calculation result sheet 51 and the calculation sheet 52 including the calculation results and the drawn graphs G1 to G3, that is, the calculation results are stored in the laying database 5. (Step S8).

  As described above, according to the simulation apparatus 1 and the simulation program, by inputting the necessary gas pressure of each demand place P3, P5, etc., each demand place P3, P5, etc. based on the laying state of the gas pipeline, etc. The amount of gas that can be supplied to the gas and the diameter of the gas pipeline in each section are calculated. That is, the amount of gas that can be supplied to each of the demand areas P3, P5,... (The gas pipeline transport capacity) corresponding to the required gas pressure of each of the demand areas P3, P5,. The diameter (required diameter) of the gas pipeline corresponding to the above is calculated. In this way, even if you do not have technical and specialized knowledge and experience, you can know the amount of gas that can be supplied to each of the demand areas P3, P5, etc., and the construction of the gas pipeline is complex Even so, the amount of gas that can be supplied to each demand place P3, P5.

  Furthermore, various parameters can be used even when determining the gas demand / gas supply capacity, gas pipeline diameter, etc. in each of the demand areas P3, P5,... So that an appropriate amount of natural gas can be supplied in the entire supply system. Are sequentially input and adjusted, and the gas supply possible amounts and the like in the demand areas P3, P5. For this reason, it becomes possible to appropriately and easily examine the gas supply amount, the transport gas pressure, the diameter of the gas pipeline, and the like in the entire supply system. Further, by inputting “closed” to the on-off valve cell C7 of the specific demand places P3, P5..., The total supply amount and the arrival amount when the gas supply is stopped in front of the specific demand places P3, P5. The gas pressure and the like can be grasped, and the gas supply system can be examined more flexibly.

  Furthermore, since the amount of gas that can be supplied to each of the demand areas P3, P5,... Is calculated based on the actual measurement value of pressure loss, it is possible to obtain a more appropriate calculation result that matches the actual pressure loss. . Further, since the gas demand amount, the gas supply possible amount, the ultimate gas pressure, and the like in the demand areas P3, P5... Are represented by graphs, it is possible to easily and appropriately grasp the gas transportation state by visual observation. For example, when the line graph G1 drops rapidly in a certain demand place P3, P5..., The ultimate gas pressure is drastically lowered in the demand place P3, P5. It is possible to determine whether the nominal diameter of the previous gas pipeline is inappropriate.

  Although the embodiment of the present invention has been described above, the specific configuration is not limited to the above embodiment, and even if there is a design change or the like without departing from the gist of the present invention, Included in the invention. For example, the gas supply to the other demand areas P3, P5... Is obtained so that only the gas demand amount at the specific demand areas P3, P5. The possible amount may be calculated. Similarly, the diameter and length of the gas pipeline in a specific section may be used as input values, and the required diameter of the gas pipeline in other sections may be calculated based on the input value. Of course, the present invention can also be applied to gases other than natural gas.

DESCRIPTION OF SYMBOLS 1 Simulation apparatus 2 Input part (input means)
3 Display unit 4 Storage unit 5 Laying database (laying information storage means)
51 Calculation Result Sheet 52 Calculation Sheet 6 Pipe Material Database 7 Simulator 71 Parameter Task (Parameter Accepting Means)
72 Calculation task (calculation means)
8 Central processing unit

Claims (4)

Computer
Laying information storage means for storing laying information including the laying state of the gas pipeline from the gas supply source to each demand place;
Parameter accepting means for accepting the supply gas pressure of the supplier and the required gas pressure of the demand area as pressure parameters, and accepting one of the gas supply / demand amount or the diameter of the gas pipeline in each demand area as a selection parameter;
Based on the laying information stored in the laying information storage means, the pressure parameter accepted by the parameter accepting means, and the selection parameter, the gas supply / demand amount not accepted by the parameter accepting means or the diameter of the gas pipeline is calculated. Calculating means to
Gas pipeline simulation program to function as   2. The gas pipeline according to claim 1, wherein the calculation unit calculates the gas supply / demand amount or the diameter of the gas pipeline based on an actual measurement value of pressure loss when the gas is transported through the gas pipeline. Simulation program. The parameter receiving means receives the length of the gas pipeline as a line length parameter,
The said calculation means calculates the said gas supply-and-demand amount or the diameter of a gas pipeline based on the line length parameter received by the said parameter reception means, The Claim 1 or 2 characterized by the above-mentioned. Gas pipeline simulation program. Laying information storage means for storing laying information including the laying state of the gas pipeline from the gas supply source to each demand place;
The input means for inputting the supply gas pressure of the supplier and the required gas pressure of the demand area as a pressure parameter, and inputting one of the gas supply and demand amount or the diameter of the gas pipeline in each demand area as a selection parameter;
Calculation for calculating the gas supply / demand amount or gas pipeline diameter not input by the input means based on the laying information stored in the laying information storage means, the pressure parameter and the selection parameter input by the input means Means,
A gas pipeline simulation apparatus comprising: