JP6430051B1 - Thermoelectric supply system construction method and construction management program - Google Patents

Abstract

To shorten the construction time of a thermoelectric supply system. A power generation unit to which a first power line from a system power supply, a first water supply pipe from a water supply source, and a first gas pipe from a gas supply source are connected; A construction method for constructing the thermoelectric supply system 12 including the heat source machine 16 connected to the second power supply line 34 from the system power supply 20 and the second gas pipe 64 from the gas supply source while being connected by the water supply pipe 54. In the state where the first power line 32, the first water supply pipe 52, and the first gas pipe 62 are connected to the power generation unit 14 as part of the construction, the first of the power generation unit 14 is used as part of the trial operation of the thermoelectric supply system 12. The trial operation is started, and the remaining construction of the thermoelectric supply system 12 is performed in parallel with the first trial operation. [Selection] Figure 3

Description

  The technique which this application discloses relates to the construction method and construction management program of a thermoelectric supply system.

  When installing fuel cell power generation equipment, install the foundation on the foundation laid on the ground at the construction site, install multiple units on the foundation with anchor bolts, and connect the foundation side piping to the unit side piping at the connection port There is a construction method for connecting to the cable (for example, see Patent Document 1).

JP 2008-282676 A

  In a thermoelectric supply system including a power generation unit and a heat source machine, construction is completed by performing a trial operation on the power generation unit. By the way, if this test operation takes a long time, it takes a long time as a construction time.

  In view of the above facts, the present invention aims to shorten the construction time of a thermoelectric supply system.

In the first aspect, a power generation unit to which a first power line from a system power source, a first water supply pipe from a water supply source and a first gas pipe from a gas supply source are connected, and the power generation unit and the second water supply pipe A construction method for constructing a thermoelectric supply system including a heat source device connected to a second power line from the system power source and a second gas pipe from the gas supply source, wherein the power generation unit Starting the first test run of the power generation unit as part of the test run of the thermoelectric supply system with the first power line, the first water supply pipe and the first gas pipe connected as part of the construction, In the first trial operation, the inspection items related to the unconstructed portion of the thermoelectric supply system are invalidated, and the remaining construction that is construction other than the connection is performed in parallel with the first trial operation.

  In the construction method of the thermoelectric supply system, the first trial operation of the power generation unit is performed as part of the trial operation of the thermoelectric supply system. The first test run is performed in a state where the first power line, the first water supply pipe, and the first gas pipe are connected to the power generation unit as part of the construction of the thermoelectric supply system. That is, the test operation of the power generation unit is started without waiting for completion of the construction of the thermoelectric supply system. In parallel with the trial operation of the power generation unit, the remaining construction (remaining construction) is performed on the power generation unit and the heat source machine.

  In this way, the first trial operation, which is a trial operation of the power generation unit, and the remaining construction for the thermoelectric supply system are performed in parallel in time. Therefore, for example, after completion of the construction of the thermoelectric supply system, the construction time can be shortened as compared with a construction method in which a trial operation of the power generation unit is performed.

Moreover, in the construction method of this thermoelectric supply system, in the first trial operation, the inspection items related to the unconstructed part of the thermoelectric supply system are invalidated.

  In the first trial operation, even if the trial operation related to the unconstructed portion of the thermoelectric supply system is performed, the inspection items related to the unconstructed portion are invalidated. Therefore, the first trial run can be continued without recognizing, for example, an error or the like in the trial run for the uninstalled portion of the thermoelectric supply system.

  This “invalidation” includes the case where the inspection item itself related to the unfinished part is excluded in the first trial operation, and the case where the inspection item is inspected but the error relating to the inspection item is not recognized as an error. Including.

In a second aspect, in the first aspect, the invalidated inspection item is validated after the remaining construction, and a second trial operation that is a remaining part of the trial operation of the thermoelectric supply system is performed.

  Therefore, the inspection items invalidated in the first trial operation can be validated after the remaining construction, the second trial operation can be performed, and the trial operation can be completed.

According to a third aspect, in the second aspect, the thermoelectric supply system includes an operation member connected to the power generation unit or the heat source unit, and the power generation unit in parallel with the first test operation or the second test operation. Alternatively, the operation member is connected to the heat source machine.

  In parallel with the first trial run or the second trial run, the operation member is connected to the power generation unit or the heat source machine, so for example, compared with the construction method of performing the first trial operation and the second trial operation after the connection construction of the operation member. Thus, the construction time can be shortened.

In the fourth aspect, the first power supply line from the system power supply, the first water supply pipe from the water supply source, and the first gas pipe from the gas supply source are connected, and the power generation unit and the second water supply pipe A construction management program for performing construction management of a thermoelectric supply system including a second power line from the system power source and a heat source machine to which a second gas pipe from the gas supply source is connected. The first power line, the first water supply pipe, and the first gas pipe are connected to the power generation unit as a part of the construction. In one trial operation, the method includes causing the computer to execute a process including invalidating an inspection item related to an unexecuted portion of the thermoelectric supply system.

  Even if the first trial operation of the power generation unit is performed, the inspection items related to the uninstalled portion of the thermoelectric supply system are invalidated. That is, the inspection item itself related to the unexecuted part is excluded in the first trial operation, or the inspection item is inspected, but an error relating to the inspection item is not recognized as an error. Thereby, a 1st trial run can be continued and it can contribute to shortening of the construction time of a thermoelectric supply system.

  The present invention can shorten the construction time of the thermoelectric supply system.

Drawing 1 is a lineblock diagram showing the thermoelectric supply system of a first embodiment in the state after construction. FIG. 2 is a schematic configuration diagram of a computer of the thermoelectric supply system according to the first embodiment. FIG. 3 is a configuration diagram showing the thermoelectric supply system of the first embodiment in a state in the middle of construction. FIG. 4 is a flowchart showing the construction management control of the thermoelectric supply system of the first embodiment. FIG. 5 is a time chart in an example of the construction method of the thermoelectric supply system of the first embodiment. FIG. 6 is a time chart in an example of the construction method of the thermoelectric supply system of the comparative example. FIG. 7 is a time chart in an example different from FIG. 5 of the construction method of the thermoelectric supply system of the first embodiment. FIG. 8 is a time chart in an example different from FIGS. 5 and 7 of the construction method of the thermoelectric supply system of the first embodiment. FIG. 9 is a time chart in an example different from FIGS. 5, 7, and 8 of the construction method of the thermoelectric supply system of the first embodiment.

  A construction method of the thermoelectric supply system of the first embodiment will be described with reference to the drawings.

  As shown in FIG. 1, the thermoelectric supply system 12 includes a power generation unit 14, a heat source device 16, and a remote controller 18. The power generation unit 14 has a hot water storage unit 15 including a tank (not shown) therein. The hot water storage unit 15 may be provided inside the power generation unit 14 as described above, but may be provided independently of the power generation unit 14 and the heat source unit 16. Further, the heat source unit 16 may be provided inside the hot water storage unit 15 provided independently of the power generation unit 14.

  1 and 3, the electric wiring 30 is distinguished by a thick single line, the water supply pipe 50 is distinguished by a thick double line, and the gas pipe 60 is distinguished by a thin line and a thick double line. Moreover, in FIG. 3, the actually connected wiring and piping are shown by a solid line, and the unconnected wiring and piping are shown by a broken line.

  The power generation unit 14 and the heat source device 16 are connected to each other by a system power supply 20, a first power supply line 32, and a second power supply line 34, and are supplied with power. In the present embodiment, since the power generation unit 14 has the hot water storage unit 15, the hot water storage unit 15 is also supplied with power by the first power supply line 32.

  Further, a current sensor signal line 36 is connected to the power generation unit 14 from the system power supply 20 via the current transformer 24. A current sensor (not shown) provided in the power generation unit 14 and the current transformer 24 are electrically connected by a current sensor signal line 36. The thermoelectric supply system 12 can also supply the electric power obtained by power generation to the outside. In this case, the value of the power supplied from the thermoelectric supply system 12 is changed via the current transformer 24 to the power generation unit. 14 is transmitted and received.

  The power generation unit 14 and the heat source device 16 are connected by an inter-unit communication line 44, and transmit and receive various signals relating to, for example, hot water temperature and amount of hot water. In the configuration in which the hot water storage unit 15 is provided outside the power generation unit 14, the inter-unit communication line 44 is also connected between the power generation unit 14 and the hot water storage unit 15 and between the heat source unit 16 and the hot water storage unit 15.

  The power generation unit 14 is connected to a server 22 such as a cloud by a network communication line 42.

  A remote controller 18 is connected to the heat source device 16 by a remote control communication line 46. When the user or worker of the thermoelectric supply system 12 inputs to the remote controller 18, the input content is sent to the heat source unit 16 and the power generation unit 14. The remote controller 18 is an example of an operation member. The power generation unit 14 and the remote controller 18 or the hot water storage unit 15 and the remote controller 18 may be connected by a remote control communication line 46.

  The first power supply line 32, the second power supply line 34, the current sensor signal line 36, the inter-unit communication line 44, and the network communication line 42 are all examples of the electrical wiring 30.

  A power supply source (not shown) and a first water supply pipe 52 are connected to the power generation unit 14, and the power generation unit 14 and the heat source machine 16 are connected by a second water supply pipe 54. Further, the power generation unit 14 and the heat source device 16 are connected to a gas supply source (not shown) by a first gas pipe 62 and a second gas pipe 64, respectively. In the power generation unit 14, the gas supplied through the first gas pipe 62, for example, the city gas mainly composed of methane, is reformed into hydrogen using a part of the water supplied through the first water supply pipe 52, and the air Electric power is generated by an electrochemical reaction with oxygen in the inside. Further, in the power generation unit 14, the heat generated by the above-described electrochemical reaction or the like is applied to water that has not been used for gas reforming, and the temperature of the hot water in the hot water storage unit 15 is increased. An example of such a thermoelectric supply system is a solid oxide fuel cell (SOFC). It is also possible to send hot water from the power generation unit 14 to the heat source device 16 through the second water supply pipe 54 and further heat and raise the temperature of the hot water by the heat source device 16.

  The electric power generated by the power generation unit 14 and the hot water of the power generation unit 14 or the heat source unit 16 are respectively supplied to a desired supply destination by power supply wiring and water supply piping (not shown).

  The thermoelectric supply system 12 of the present embodiment can be installed near a supply destination, that is, a place where electric power or hot water (heat) is consumed, and is an example of a so-called distributed power source.

  A computer 70 shown in FIG. 2 is used for the trial operation for the thermoelectric supply system 12. The computer 70 may be provided in the power generation unit 14, the heat source device 16, and the remote controller 18, but is provided separately from these members so that the computer 70 is electrically connected to the thermoelectric supply system 12 during a trial operation. It may be.

  The computer 70 includes a central processing unit (CPU) 72, a random access memory (RAM) 74, a read only memory (ROM) 76, a hard disk drive (HDD) 78, and an input / output port (I / O) 80. . Further, the computer 70 includes a bus 82 such as a data bus or a control bus for connecting these members. Instead of the HDD 78, a storage device using a nonvolatile memory such as an SSD (Solid State Drive) or an ODD (Optical Disc Drive) may be used.

  A UI (User Interface) 84 and a sensor unit 86 are connected to the I / O 80. The UI 84 includes, for example, an operation unit 84A and a display unit 84B. The operation unit 84A receives an instruction from a construction worker as will be described later. The display part 84B notifies the test operation status in the construction work. The operation unit 84A is a device that receives an input operation of a construction worker and notifies the CPU 72 of the operation, and for example, a keyboard, a mouse, a microphone, or the like is used. The display unit 84B is a device that displays information generated by the CPU 72 as an image. For example, a liquid crystal display, an organic EL (Electroluminescence) display, or the like is used. As the UI 84, it is also possible to use a touch panel in which the operation unit 84A and the display unit 84B are integrated.

  The sensor unit 86 connected to the I / O 80 detects operation states of the power generation unit 14, the heat source device 16, and the remote controller 18 in the thermoelectric supply system 12. Further, the sensor unit 86 has a current value detected by the current sensor, a communication state of the network communication line 42, a communication state of the inter-unit communication line 44, a communication state of the remote control communication line 46, a water supply state of the water supply pipe 50, and a gas pipe 60. Various abnormalities relating to the gas supply state, the hot water temperature of the hot water storage unit 15 and the heat source unit 16, the amount of hot water, and the like are detected.

  The ROM 76 or the HDD 78 stores a construction management program. At the time of construction of the thermoelectric supply system 12, the CPU 72 reads a construction management program stored in the ROM 76 or the HDD 78, and operates according to this construction management program.

  In the present embodiment, as a test operation as a whole of the thermoelectric supply system 12, a test operation (first test operation) of only the power generation unit 14 is first performed, and then the remaining test operation other than the first test operation is performed as the second test operation. Perform a test run.

  FIG. 3 shows a connection state of the electric wiring 30, the water supply pipe 50, and the gas pipe 60 of the thermoelectric supply system 12 when the first trial operation is performed. When performing the first trial operation, the first power line 32, the first water supply pipe 52, and the first gas pipe 62 are connected to the power generation unit 14 as part of the construction of the thermoelectric supply system 12 (shown by a solid line in FIG. 3). ). However, in the thermoelectric supply system 12, other electrical wiring, water supply piping, and gas piping are not connected (uninstalled state) (shown by broken lines in FIG. 3).

  In parallel with the first trial operation for the power generation unit 14, an unexecuted portion, that is, remaining construction is performed on the power generation unit 14, the heat source device 16, and the remote controller 18 in the construction of the entire thermoelectric supply system 12.

  FIG. 4 shows a flowchart showing a trial run process executed in the computer 70 when the thermoelectric supply system 12 is constructed in this way.

  First, in step S12, it is determined whether or not a start operation of the first trial operation has been performed. If it is determined that the first test operation start operation has not been performed, it is determined in step S12 whether or not the first test operation start operation has been performed. The start operation of the first test run is, for example, an input operation to the first test run start switch provided in the operation unit 84A or the power generation unit 14.

  If it is determined in step S12 that the first trial operation has been started, the process proceeds to step S14. In step S14, the inspection items related to the unexecuted part are invalidated.

  In the next step S16, the power generation unit 14 is activated and the first trial operation is started. As described above, since the first power supply line 32, the first water supply pipe 52, and the first gas pipe 62 are connected to the power generation unit 14, a part necessary for performing the first test run on the power generation unit 14 is established. Can be activated.

  In step S18, the power generation unit 14 is determined whether there is no abnormality in the first trial operation. In step S14, since the inspection items related to the non-executed part have already been invalidated, no abnormality is detected for the non-executed part. That is, in step S18, it is determined whether there is an abnormality in the inspection item that has not been invalidated. For this reason, the first trial operation of the power generation unit 14 can be continuously performed without being disabled or stopped due to the influence of the unconstructed part.

  If it is determined in step S18 that there is an abnormality, in step S20, the inspection item having the abnormality is displayed on the display unit 84B or the like, and the process returns to step S18. The construction worker can identify the abnormal part and the content of abnormality in the first trial operation from the display on the display unit 84B and the like, and can eliminate the abnormality. In step S18, it is determined whether there are any abnormalities for all inspection items that have not been invalidated.

  If it is determined in step S18 that there is no abnormality, the process proceeds to step S22, and the inspection items that have been invalidated so far are validated. In the present embodiment, all inspection items in the thermoelectric supply system 12 are validated.

  As described above, in the present embodiment, the remaining construction of the entire thermoelectric supply system 12 is performed in parallel with the trial operation (first trial operation) of the power generation unit 14. Therefore, when the remaining construction is completed in the middle of the first trial operation or after the completion of the first trial operation, the second trial operation for the entire thermoelectric supply system 12 can be performed. Even if the remaining construction is not completed, a part of the second trial operation may be possible depending on the inspection item.

  In step S24, it is determined whether or not a start operation of the second trial operation has been performed. Specifically, as in step S12, the determination can be made based on, for example, the presence or absence of an input operation to the second trial operation start switch provided in the power generation unit 14. If it is determined that the second trial operation start operation has not been performed, it is determined in step S24 whether or not the second trial operation start operation has been performed.

  If it is determined in step S24 that the start operation of the second trial operation has been performed, in step S26, the thermoelectric supply system 12 is activated and the second trial operation is started. Since all the inspection items of the thermoelectric supply system 12 are validated, the second trial operation can be performed.

  In step S28, it is determined whether there is any abnormality in the second trial operation for the entire thermoelectric supply system 12. If it is determined in step S28 that there is an abnormality, in step S30, the inspection item having the abnormality is displayed on the display unit 84B or the like, and the process returns to step S28. The construction worker can identify an abnormal part and an abnormal content in the second trial operation from the display on the display unit 84B and the like, and can eliminate the abnormality. In step S28, it is determined whether or not there is an abnormality for all the inspection items.

  If it is determined in step S28 that there is no abnormality, the trial run is terminated in step S32, and this process is terminated.

  FIG. 5 shows an example of a time chart required for construction in the construction method of the present embodiment. FIG. 6 shows a time chart required for construction in the construction method of the comparative example. In these time charts, the construction time of the power generation unit 14 is indicated by an arrow T1. Of the remaining construction in the thermoelectric supply system 12, construction times for the electrical wiring 30, the water supply pipe 50, and the gas pipe 60 are indicated by arrows T2, T3, and T4, respectively. Furthermore, the time required for the first trial operation and the second trial operation is indicated by arrows TA and TB, respectively.

  In the time charts shown in FIGS. 5 and 6, the construction is performed in the order of the electrical wiring 30 (time T2), the water supply pipe 50 (time T3), and the gas pipe 60 (time T4). It is determined according to the configuration of the thermoelectric supply system 12 and the situation at the construction site. There is a case where the order of construction of the electric wiring 30, the water supply pipe 50, and the gas pipe 60 is not particularly limited, and there are cases where a part or all of these constructions can be performed in parallel as will be described later. And in the construction method of a comparative example, after all construction of the electrical wiring 30, the water supply piping 50, and the gas piping 60 is complete | finished, the 1st test run is performed.

  On the other hand, in the construction method of the first embodiment, construction necessary for the first trial operation is performed on the power generation unit 14, and after the construction is completed, the first trial operation and the remaining construction are performed in parallel. Substantially, the start of the first trial run does not wait for the completion of the construction of the thermoelectric supply system 12 but precedes this. Therefore, the time from the construction start time TS to the first trial operation end time TE is shorter than the comparative example. And thereby, in 1st embodiment, shortening of the construction time of the thermoelectric supply system 12 can be aimed at.

  Moreover, in the first embodiment, the construction necessary for the first trial operation is performed on the power generation unit 14, and this construction is a part of the construction of the thermoelectric supply system 12. For this reason, the construction required for the first trial operation performed on the power generation unit 14 is not wasted. Further, the first test operation performed on the power generation unit 14 is also a part of the test operation on the entire thermoelectric supply system 12, and it is not necessary to repeat the test operation on the power generation unit 14.

  In both the first embodiment and the comparative example, the second trial operation is performed. However, the second trial operation is performed after the first trial operation in the examples illustrated in FIGS. 5 and 6. Therefore, in the first embodiment, the second trial operation does not affect the effect of shortening the construction time as compared with the comparative example. And in this embodiment, the time from construction start time TS to 2nd trial run end time TF is also shorter than a comparative example. In addition, in the construction method of the comparative example, actually, the first test operation and the second test operation are not distinguished from each other as described above, and the test operation is performed as an example process.

  In this embodiment, “invalidation” of inspection items related to unexecuted parts means that the inspection items themselves related to unexecuted parts are excluded from the actual first trial operation, and the inspection items are not inspected. including. However, “invalidation” is not limited to this, for example, inspection is performed for inspection items related to unexecuted parts. This includes not displaying on the part 84B or the like. In any case, when it is determined that there is an abnormality in the inspection items related to the unexecuted part, the construction operator does not recognize this as an error or the like, and can continue the first trial operation as it is.

  By the way, in the example shown in FIG. 5, the completion of all construction of the electrical wiring 30, the water supply pipe 50, and the gas pipe 60 is waited, the invalidated inspection items are validated, and the second trial operation is performed.

  On the other hand, in the example shown in FIG. 7, the electric wiring 30, the water supply pipe 50, and the gas pipe 60, which are unconstructed parts of the thermoelectric supply system 12, correspond to the construction completion part when a part of the construction is completed. This is a construction method that sequentially validates the inspection items to be performed and performs the second trial operation. Specifically, in the example of FIG. 7, when the construction of the electrical wiring 30 (time T2) is completed, the second trial operation (time TB2) of the corresponding part is performed. And after construction of the electrical wiring 30, construction of the water supply pipe 50 (time T3) is performed, and when this construction is completed, a second trial operation (time TB3) of the corresponding part is performed. Furthermore, after construction of the water supply pipe 50, construction of the gas pipe 60 (time T3) is performed, and when this construction is completed, a second trial operation (time TB4) is performed. Thereby, it is possible to start a 2nd trial run earlier compared with the construction method shown in FIG. In other words, since part of the second trial operation is also performed in parallel with the first trial operation, the construction time of the thermoelectric supply system 12 can be further shortened. Moreover, it is also possible to perform different types of second test operations in parallel, thereby further shortening the construction time of the thermoelectric supply system 12.

  Further, as in the example shown in FIGS. 8 and 9, in the construction of the electrical wiring 30, the water supply pipe 50 and the gas pipe 60 which were unconstructed parts, some or all of these constructions may be performed in parallel. Good.

  The construction method shown in FIG. 8 performs part of the construction of the electrical wiring 30, the water supply pipe 50, and the gas pipe 60 in parallel, waits for the completion of these constructions, validates the inspection items that have been invalidated, This is an example of performing two trial runs. In this construction method, since the construction of the electrical wiring 30, the water supply pipe 50, and the gas pipe 60 is performed in parallel, the time of completion of these constructions (in the example of FIG. 8, the construction of the gas pipe 60 (see time T4)) 5 is faster than the construction method shown in Fig. 5. As a result, the second trial operation can be started earlier, so that the construction time of the thermoelectric supply system 12 can be further shortened.

  The construction method shown in FIG. 9 performs construction of the electrical wiring 30, the water supply pipe 50 and the gas pipe 60 in parallel, and at the stage where part of construction (the electrical wiring 30 in the example of FIG. 9) is completed, This is an example in which the inspection items corresponding to are sequentially enabled, but the second trial operation is not performed in parallel, but is performed as a series of steps. Even if it is the construction method shown in FIG. 9, while being able to start a 2nd trial run early, a 1st trial run and a 2nd trial run can be performed partially in parallel. Thereby, the construction time of the thermoelectric supply system 12 can be further shortened.

  Each of the above construction methods is an example in which the second trial operation is performed and the construction of the thermoelectric supply system 12 is completed upon completion of the second trial operation. However, in each of the examples of the construction methods, the remaining construction is performed on the thermoelectric supply system 12 in parallel with the first trial operation regardless of whether or not the second trial operation is performed. For this reason, any construction method is effective in reducing the construction time of the thermoelectric supply system 12. And since the 1st test run is performed reliably, aiming at shortening of the construction time of the thermoelectric supply system 12, the construction quality with respect to the electric power generation unit 14 can be ensured. Furthermore, construction quality in the entire thermoelectric supply system 12 can be ensured by performing the second trial operation.

  In each construction method of the present embodiment, the construction of the electric wiring 50 includes construction (connection construction) of the remote controller 18 which is an example of the operation member. And construction of remote control 18 is performed in parallel with at least one of the 1st trial run (time TA) and the 2nd trial run (time TB), as shown in the time chart of Drawing 5 and Drawings 7-9. Therefore, the construction time can be shortened as compared with the construction method in which the first trial operation and the second trial operation are performed after the construction of the remote controller 18.

12 thermoelectric supply system 14 power generation unit 16 heat source machine 18 remote control (an example of operation member)
20 system power supply 22 server 24 current transformer 30 electrical wiring 32 first power supply line 32 first power supply line 34 second power supply line 36 current sensor signal line 42 network communication line 44 inter-unit communication line 46 remote control communication line 50 water supply pipe 52 One water supply pipe 54 Second water supply pipe 60 Gas pipe 62 First gas pipe 64 Second gas pipe 70 Computer

Claims (4)

A power generation unit to which a first power line from a system power source, a first water supply pipe from a water supply source, and a first gas pipe from a gas supply source are connected;
A heat source machine connected to the power generation unit and a second water supply pipe, to which a second power line from the system power supply and a second gas pipe from the gas supply source are connected,
A construction method for constructing a thermoelectric supply system including
A first trial run of the power generation unit as part of a trial run of the thermoelectric supply system with the first power line, the first water supply pipe and the first gas pipe connected to the power generation unit as part of the construction. Start,
In the first trial operation, the inspection items related to the unconstructed part of the thermoelectric supply system are invalidated,
A construction method for a thermoelectric supply system that performs remaining construction that is construction other than the connection in parallel with the first trial operation. The construction method of the thermoelectric supply system according to claim 1 , wherein the invalidated inspection item is validated after the remaining construction and a second trial operation that is a remaining part of the trial operation of the thermoelectric supply system is performed. The thermoelectric supply system includes an operation member connected to the power generation unit or the heat source machine,
The construction method of the thermoelectric supply system of Claim 2 which performs the connection construction of the said operation member to the said electric power generation unit or the said heat source machine in parallel with said 1st trial run or said 2nd trial run. A power generation unit to which a first power line from a system power source, a first water supply pipe from a water supply source, and a first gas pipe from a gas supply source are connected;
A heat source machine connected to the power generation unit and a second water supply pipe, to which a second power line from the system power supply and a second gas pipe from the gas supply source are connected,
A construction management program for managing the construction of a thermoelectric supply system including
First test run of the power generation unit as part of a test run of the thermoelectric supply system in a state where the first power line, the first water supply pipe, and the first gas pipe are connected to the power generation unit as part of the construction. The construction management program which makes a computer perform the process including invalidating the inspection item relevant to the non-construction part of the said thermoelectric supply system.