JP3942512B2 - Transmission plan creation method and transmission plan creation program - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power transmission plan creation method and a power transmission plan creation program for creating a power transmission plan for a consumer from a power generation system.
[0002]
[Prior art]
As a result of the liberalization of the electricity retail business, those who have power generation facilities, even if they are not existing power companies, can now sell the power generated by power generation to consumers. For example, in dam management offices that manage dams, it has traditionally been necessary to cover the power used by the dam management office itself by turning the turbine when discharging water and generating electricity. It is also possible to sell surplus power after use.
[0003]
In other words, a power generation system composed of a power generation facility (for example, a dam) and a power consuming device (for example, a dam management station) is constructed, and surplus power in the power generation system (from power generated by the power generation facility is consumed at the dam management station). It is possible to carry out a power retail business in which power is subtracted and sold to the outside for sale. However, if a power company that implements a power retail business uses a transmission line owned by an existing power company to transmit power, the power demand amount and transmission from the power generation system within the specified period will be It may be necessary to achieve simultaneous and same amount control to match the amount of electric power.
[0004]
[Problems to be solved by the invention]
However, conventionally, in a power generation system including a power generation facility and a power consuming device, when the ratio of power demand in the power consuming device to the generated power is large, surplus power that can be transmitted to the outside can be estimated with high accuracy. It was difficult. As mentioned above, it is necessary to estimate the exact surplus power in order to achieve the same amount control simultaneously, but the surplus power that can be transmitted to the outside is not accurately estimated in the conventional system. It was uncertain whether or not the same amount control could be achieved.
[0005]
The present invention has been made in view of the above-described problems, and an object of the present invention is to transmit power capable of deriving power that can be transmitted from an electric power generation system to an external consumer and creating an appropriate power transmission plan. The point is to provide a plan creation method and a transmission plan creation program.
[0006]
[Means for Solving the Problems]
  The first characteristic configuration of the power transmission plan creation method according to the present invention for solving the above-described problems is as described in claim 1 in the section of the claims, and includes one or a plurality of power generation facilities and necessary for operation. Receive power from the generator or generatorsMultipleA power transmission plan creation method for creating a power transmission plan from a power generation system including a power consumption device to a consumer,Classifying the plurality of power consuming devices into a first device operated in a steady pattern and a second device operated in connection with the occurrence of a specific event;SaidMultipleWith reference to the power demand determination step for determining the time fluctuation characteristics of each power demand of the power consuming device, the time fluctuation characteristics of the power demand and the time fluctuation characteristics of the generated power by the one or more power generation facilities, A surplus power estimation step for estimating a time variation characteristic of surplus power in the power generation system, and a power transmission for creating a transmission plan of transmission power that can be transmitted to the consumer based on the surplus power estimated in the surplus power estimation step And a plan creation process.Here, the steady pattern is a predetermined operation pattern for the power consuming apparatus. As a result, the time fluctuation characteristic of the power demand of the power consuming apparatus that operates in a steady pattern is known or can be estimated with very high accuracy.
[0008]
  In order to solve the above problems, a power transmission plan creation method according to the present inventionsecondThe characteristic configuration of theClaim 2As described abovefirstIn addition to the above characteristic configuration, the time fluctuation characteristic of the power demand of the second device is determined based on the implementation schedule of the event.
[0009]
  In order to solve the above problems, a power transmission plan creation method according to the present inventionThirdThe characteristic configuration of theClaim 3As described aboveFirst or secondIn addition to the characteristic configuration of the above, the power generation system operates by utilizing heat received from the combined heat and power facility and the combined heat and power facility that generates heat and electricity as part or all of the power generation facility. Or a heat demand determining step comprising a plurality of heat consuming devices, and determining a time variation characteristic of the heat demand of each of the one or more heat consuming devices, and the generated power of the one or more power generation facilities The time variation characteristic is determined with reference to the time variation characteristic of electric power generated when the combined heat and power supply facility is operated so as to supply heat corresponding to the time variation characteristic of the heat demand.
[0010]
  In order to solve the above problems, a power transmission plan creation method according to the present inventionFourthThe characteristic configuration of theClaim 4As described aboveThirdIn the heat demand determination step, in the heat demand determination step, the one or more heat consuming devices are operated in association with the occurrence of a specific event with the third device operated in a steady pattern. It is classified into the apparatus, and the time fluctuation characteristic of the heat demand is determined.
[0011]
  In order to solve the above problems, a power transmission plan creation method according to the present inventionFifthThe characteristic configuration of theClaim 5As described aboveFourthIn addition to the above characteristic configuration, the time fluctuation characteristic of the heat demand of the fourth device is determined based on an execution schedule of the event.
[0012]
  In order to solve the above problems, a power transmission plan creation method according to the present inventionSixthThe characteristic configuration of theClaim 6As described above, from the firstFifthIn addition to any of the characteristic configurations, the one or more power generation facilities include a thermoelectric conversion facility that generates power using waste heat in the power generation system, and the amount of waste heat that the thermoelectric conversion facility can use. A waste heat amount determining step for determining a time variation characteristic, wherein the time variation characteristic of the generated power by the one or more power generation facilities is determined using the waste heat amount determined in the waste heat amount determination step. This is in the point determined with reference to the time fluctuation characteristics of the electric power generated when the system is operated.
[0013]
  The characteristic configuration of the power transmission plan creation program according to the present invention for solving the above-mentioned problems is described in the claims section.Claim 7As described in claim 1,Claim 6It is a point which is a program for making a computer perform each said process of the power transmission plan preparation method of any one of these.
[0014]
  The operation and effect will be described below.
  According to the first characteristic configuration of the power transmission plan creation method according to the present invention, in the power demand determination step,The plurality of power consuming devices are classified into a first device that is operated in a steady pattern and a second device that is operated in association with the occurrence of a specific event, whereby the power of the first device is The time fluctuation characteristic of demand can be estimated with high accuracy, and the time fluctuation characteristic of the power demand of the second device is not known, but assuming the occurrence of a specific event, the time of power demand at that time Fluctuation characteristics can be estimated. Therefore,SaidMultipleAnd determining the time fluctuation characteristics of each power demand of the power consuming apparatus, and referring to the time fluctuation characteristics of the power demand and the time fluctuation characteristics of the power generated by the power generation facility in the surplus power estimation step, Estimating the time fluctuation characteristics of surplus power in the transmission plan creation step, creating a transmission plan of transmission power that can be transmitted to the consumer based on the surplus power estimated in the surplus power estimation step, Even when simultaneous power control is required when power is transmitted from this power generation system to customers, it is easy to achieve the same power control because the transmittable power (surplus power) is estimated with high accuracy. become.
[0016]
  The power transmission plan creation method according to the present inventionsecondAccording to the characteristic configuration, since the operation schedule of the second device can be determined based on the event execution schedule, the power consumption schedule (time fluctuation characteristics of power demand) by each device is accurately estimated. be able to.
[0017]
  The power transmission plan creation method according to the present inventionThirdIn the heat demand determination step, the time variation characteristic of the heat demand of each of the one or more heat consuming devices is determined, so that heat corresponding to the time variation characteristic of the heat demand is generated. It is possible to accurately estimate the temporal variation characteristic of electric power generated when the cogeneration facility is operated so as to be supplied. As a result, even when simultaneous power control is required when power is transmitted from this power generation system to the customer, the transmittable power (surplus power) can be estimated with high accuracy. Simultaneously the same amount control can be achieved easily.
[0018]
  The power transmission plan creation method according to the present inventionFourthAccording to the characteristic configuration, the one or more heat consuming devices are classified into a third device operated in a steady pattern and a fourth device operated in association with occurrence of a specific event. Thus, the time fluctuation characteristic of the heat demand of the third apparatus can be estimated with high accuracy, and the time fluctuation characteristic of the heat demand of the fourth apparatus is not known, but a case where a specific event occurs is assumed. Thus, it is possible to estimate the time fluctuation characteristics of the heat demand at that time.
[0019]
  The power transmission plan creation method according to the present inventionFifthSince the operation schedule of the fourth device can be determined based on the event execution schedule, the heat consumption schedule (thermal fluctuation characteristics of heat demand) by each device can be accurately estimated. be able to.
[0020]
  The power transmission plan creation method according to the present inventionSixthAccording to the characteristic configuration of the above, when heat is generated in the power generation system, and the one or more power generation facilities include a thermoelectric conversion facility that generates power using the waste heat, a waste heat amount determination step Therefore, the time variation characteristic of the amount of waste heat that can be used by the thermoelectric conversion facility is determined, so that the time variation characteristic of the electric power generated when the thermoelectric conversion facility is operated using the amount of waste heat can be accurately determined. Can be estimated. As a result, even when simultaneous power control is required when power is transmitted from this power generation system to the customer, the transmittable power (surplus power) can be estimated with high accuracy. Simultaneously the same amount control can be achieved easily.
[0021]
According to the characteristic configuration of the power transmission plan creation program according to the present invention, the same effects as those described above by the power transmission plan creation method according to the present invention can be obtained by causing the computer to execute each step in the power transmission plan creation method. Can do.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a diagram schematically showing a flow of information and power when creating a power transmission plan for transmitting power generated in the power generation system 3 to a customer 6 via a transmission line.
[0023]
The power generation system 3 includes a power generation facility 1 and a power consuming device 2 that receives power necessary for operation from the power generation facility, and can transmit surplus power to an external customer via a transmission line. However, when the ratio of the power demand of the power consuming device 2 to the generated power of the power generation facility 1 is large, surplus power that can be transmitted to the consumer 6 varies greatly according to the power demand of the power consuming device 2. , Likely to be uncertain. As a result, the electric utility 5 that has received the transmission request from the customer 6 receives an accurate transmission plan (time variation characteristics of the transmission power) of the power generation system 3 from the transmission plan creation system 4, and It is necessary to conclude a power supply contract between the two. Although FIG. 1 shows a case where one power generation system 3 is connected to one power transmission plan creation system 4, a plurality of power generation systems 3 are connected to one power transmission plan creation system 4. It does not matter if you are.
[0024]
In the power generation system 3, the power consuming devices 2 are classified into a plurality of types. In the present embodiment, the power consuming devices 2 are classified into a first power consuming device 2a, a second power consuming device 2b, and a third power consuming device 2c as described later. Yes. Since the first power consuming device 2a is operated in a steady pattern, the time variation characteristic of power demand is known, or the time variation characteristic of power demand can be estimated with very high accuracy. Since the second power consuming device 2b and the third power consuming device 2c are not operated in a steady pattern, the time variation characteristics of power demand are unknown, but they are operated in relation to the occurrence of a specific event. Therefore, it is possible to estimate the time fluctuation characteristic of the power demand with reference to the event execution schedule.
[0025]
Examples of the event include “entry of LNG ship” in which a specific implementation schedule is designated, and “gas production” in which a specific implementation schedule is not designated. Therefore, when an event of “entry of LNG ship” occurs, the operation schedule of each power consuming device is easily determined based on the event execution schedule (for example, scheduled arrival date and time of LNG ship). As a result, the time fluctuation characteristic of the power demand is determined. In addition, it is known to the power transmission plan creation system 4 which power consuming device (one or a plurality) among all the power consuming devices is operated in response to the occurrence of an event “entry of an LNG ship”, for example. If an event of “gas production” occurs, information on the operation schedule of the power consuming apparatus is determined based on an event (production plan) such as what kind of gas is produced and how much, and the operation schedule is further determined. It is possible to estimate the time fluctuation characteristics of the power demand by referring to the information regarding. Similarly, it is known to the power transmission plan creation system 4 which power consuming device (s) among all the power consuming devices is operated with the occurrence of the event “gas production”.
[0026]
Therefore, the power transmission plan creation system 4 collects information related to the production plan of the third power consuming device 2c, and determines the operation schedule by the third power consuming device 2c, and the second power consuming device. 2b and the operation schedule determination means 7, and the power demand determination means 8 which collects the information regarding an operation schedule and determines the time fluctuation characteristic of the power demand by the 2nd power consumption apparatus 2b and the 3rd power consumption apparatus 2c. .
[0027]
In FIG. 1, the time variation characteristics of the power demand, the operation schedule, and the production plan from each of the first power consuming device 2 a, the second power consuming device 2 b, and the third power consuming device 2 c to the power transmission plan creating system 4. However, in reality, a device for managing the information is provided separately and is automatically placed in a state where it can be automatically used in the power transmission plan creation system 4. Shall.
[0028]
Next, the information regarding the time fluctuation characteristic of the power demand by the power consuming apparatus 2 (2a to 2c) is collected in the surplus power estimating means 9. The surplus power estimation means 9 also collects information regarding the time variation characteristics of the generated power of the power generation facility 1. As a result, the surplus power estimation means 9 can estimate the surplus power time variation characteristic in the power generation system 3 with reference to the time variation characteristic of the generated power and the time variation characteristic of the power demand.
[0029]
Information on the time fluctuation characteristics of surplus power is collected by the power transmission plan creating means 10, and the power transmission plan creating means 10 converts the transmission power transmission plan (time fluctuation characteristics of the transmitted power) that can be transmitted to the customer 6 to the surplus power. Based on this, the plan is transmitted to the electric utility 5. Here, when it is necessary to create a transmission plan every 30 minutes (time fluctuation characteristics of transmission power every 30 minutes), at least every 30 minutes using the operation schedule of the power consuming device 2 every 30 minutes. It is preferable to determine the time fluctuation characteristics of the power demand.
[0030]
As described above, the power transmission plan creation system 4 is constructed by functions of information input, information processing, and information output, and thus is configured by general hardware such as an information input / output unit, an arithmetic processing unit, and an information storage unit. It can be realized by a computer. Therefore, in the following embodiment, an example in which the power transmission plan creation method according to the present invention is executed by the power transmission plan creation system 4 realized by a computer will be described with reference to a display screen example in the display device of the computer. .
[0031]
In the following embodiment, as an example of the power generation system 3, as shown in FIG. 2, an equipment including an LNG receiving / storage facility for receiving and storing LNG from an LNG (liquefied natural gas) ship and a gas production facility is taken as an example. The present invention will be described with reference. Each of the LNG receiving / storage facility and the gas production facility includes various power consuming devices 2 such as a prime mover, a pump, a measuring device, an air conditioner, an office device, and a lighting device. In order to supply electric power, one or a plurality of power generation facilities 1 are provided.
[0032]
<Power demand determination process>
3 to 5 exemplify the display of the power demand determination process in which the determination of the time variation characteristics of the power demand in the first power consuming device 2a to the third power consuming device 2c is performed in the power transmission plan creating system 4. It is an example of a screen.
First, FIG. 3 shows that the operation is performed in a steady pattern (predetermined operation pattern), so that the time fluctuation characteristic of the power demand is known, or the time fluctuation characteristic of the power demand is very high accuracy. This is the case of the first power consuming device 2a that can be estimated by Examples of the first power consuming device 2a include a device that operates for a certain period with a certain output, such as a lighting device or a pump. Information on the time fluctuation characteristics of the power demand of the first power consuming apparatus 2a is created in advance, and is placed in a state where it can be automatically used in the power transmission plan creation system 4. Alternatively, the operator of the power transmission plan creation system 4 may input the time fluctuation characteristics of the power demand of the first power consuming device 2 a to the power transmission planning system 4. As a result, the time fluctuation characteristic of the power demand of the first power consuming apparatus 2a is determined.
[0033]
Therefore, in the case of the “large circulating water pump” in the display example of FIG. 3, there is a demand of 230 (kW) continuously from April 5 to April 11, and the “small circulating water pump” Also, it can be seen from the numerical value input column 21 that there is a demand of 50 (kW) continuously from April 5 to April 11. The information displayed here is input by the operator of the power transmission plan creation system 4 into the numerical value input field 21 (power demand (kW) and check box every 30 minutes).
[0034]
Therefore, the time fluctuation characteristic of the power demand of the “large circulating water pump” in the first power consuming device 2a as shown in the power demand column 20 is a constant power of 230 (kW) from 0:00 to 24:00. The information that there is is transmitted to the surplus power estimation means 9. In addition, there is surplus information that the “night illumination” in the first power consuming device 2a has power demand (for example, 10 kW) between time 0:00 and 6:00 and time 18:00 to 24:00. This is transmitted to the power estimation means 9.
[0035]
Next, FIG. 4 shows that the operation is performed in association with the occurrence of a specific event, so that the power demand determination means 8 estimates the time fluctuation characteristics of the power demand with reference to the implementation schedule of the event. This is the case of the second power consuming device 2b capable of performing the above. Examples of such events include “entering LNG ships” and “gas production”. Information regarding the implementation schedule of such events is created in advance, and is automatically put into a usable state in the power transmission plan creation system 4. Alternatively, the operator of the power transmission plan creating system 4 may input information related to the execution schedule of a predetermined event to the power transmission planning system 4.
[0036]
FIG. 4 shows a specific example. The time fluctuation characteristics of the power demand when receiving LNG from the LNG ship to the LNG receiving / storage facility are the scheduled arrival date and time of the LNG ship as an example of the implementation schedule. It is an example in the case of being determined based on the scheduled departure date and time. The LNG receiving and storage facilities here are constructed with multiple power consuming devices, such as facilities that handle natural gas at high pressure and facilities that handle at medium pressure, and the power demand when each facility is operated, Shows the operation schedule of each facility based on the scheduled arrival and departure date and time. Specifically, the LNG storage facility comprises a high-voltage dedicated facility with a power demand of 760 (kW), a high-pressure department with a power demand of 760 (kW), and a medium-pressure department with a power demand of 520 (kW). Medium / high voltage equipment A, medium / high voltage equipment B with power demand of 760 (kW) and medium / high voltage equipment B with power demand of 520 (kW) It consists of four power consuming equipment groups of pressure-dedicated equipment. The numerical value of the demand power shown in FIG. 4B is input by the operator of the power transmission plan creation system 4. Then, the operator similarly inputs the scheduled arrival date and time and the scheduled departure date, which are information relating to the event implementation schedule.
[0037]
As shown in FIG. 4 (b), the power demand determining means 8 can determine from the scheduled arrival date and time of the LNG ship to 2 hours after the scheduled departure date and time when the scheduled arrival date and the scheduled departure date are determined. Has a predetermined operation schedule in which the high-pressure department of the medium- and high-pressure equipment A, the medium-pressure department of the medium- and high-pressure department B, and the medium-pressure dedicated equipment will operate. 8 automatically determines the power demand during that time as 760 (kW) +520 (kW) +380 (kW) = 1660 (kW). In addition, since there is a schedule that the high-pressure department of the medium- and high-pressure equipment A and the medium-pressure dedicated equipment will operate from 2 hours before the scheduled arrival date and time until the scheduled arrival date and time, the power demand decision The means 8 automatically determines the power demand during that time as 760 (kW) +380 (kW) = 1140 (kW). Similarly, medium and high pressure equipment A is 10 hours before the scheduled arrival date and 2 hours before the scheduled arrival date and 2 hours after the scheduled departure date and 10 hours after the scheduled departure date and time. Also has an operation schedule in which the high-pressure department and the medium-pressure dedicated facility operate, and the power demand determining means 8 automatically sets the power demand between 520 (kW) +380 (kW) = 900 (kW). To decide. Furthermore, there is also an operation schedule in which the medium pressure dedicated equipment operates until 10 hours before the scheduled arrival date and after 10 hours after the scheduled departure date, and the power demand determining means 8 The power demand is automatically determined as 380 (kW).
[0038]
As a result of the above, the time fluctuation characteristics of power demand every 30 minutes when receiving LNG from the LNG ship to the LNG receiving / storage facility (a type of power consuming device 2) is determined by a graph as shown in FIG. Is done.
[0039]
Next, FIG. 5 shows that the information about the production plan of the gas that is the product is known for the event “gas production”, and the operation schedule determination means 7 refers to the information about the production plan. In this example, the information regarding the operation schedule (event execution schedule) can be determined, and the power demand determination means 8 can determine the time fluctuation characteristics of the power demand with reference to the information regarding the operation schedule. is there. Information relating to this production plan is created in advance and is automatically available in the power transmission plan creation system 4. Alternatively, the operator of the power transmission plan creating system 4 may input a production plan using the third power consuming device 2 c to the power transmission planning system 4. Below, the case where the operator of the power transmission plan creation system 4 inputs the production plan using the 3rd power consumption apparatus 2c with respect to the power transmission planning system 4 is illustrated.
[0040]
In the gas production facility illustrated in FIG. 2, for example, 60 km between time 12:30 and time 18:45³When a gas delivery plan (production plan) for producing gas at / h and delivering it to a gas consumer is input to the numerical value input field 25 in FIG. 5, the operation schedule determination means 7 stores the gas production held in advance. Production capacity of equipment (third power consuming device 2c) (for example, how many km per hour³In consideration of the information on whether or not the gas can be produced), an operation schedule (event execution schedule of “gas production”) on which schedule the gas production facility operates is automatically determined. This operation schedule is transmitted to the electric power demand determining means 8, and the electric power demand determining means 8 considers the rated electric power of the gas production facility (a plurality of electric power consumption facilities 2c such as an LNG pump and a seawater pump), etc. The time fluctuation characteristic of the power demand as shown in 24 is automatically determined.
[0041]
<Surplus power estimation process>
The time fluctuation characteristic of the power demand determined as described above is transmitted to the surplus power estimation means 9, and the total power demand by all the power consuming devices is automatically derived as shown in FIG. Further, since the time fluctuation characteristic of the generated power from the power generation facility 1 as shown in FIG. 7 is also transmitted to the surplus power estimating means 9, the time fluctuation of the surplus power of the power generation system 3 is obtained by subtracting the power demand from the generated power. The characteristic is estimated by the surplus power estimating means 9. Here, the power generation facility 1 can estimate the generated power from the expected temperature (because the fuel concentration changes with the outside temperature and affects the generated power) and the number of operating units.
[0042]
<Transmission plan creation process>
FIG. 8 shows an example of a screen on which a power transmission plan is created. Here, the time fluctuation characteristic of the surplus power estimated by the surplus power estimation means 9 is first displayed as a graph as the transmittable power. Furthermore, a power transmission plan in which the power value previously input by the operator of the power transmission plan creating system 4 in the numerical value input field 26 is the power (scheduled power transmission) to be transmitted from the power generation system 3 to the customer 6 via the power transmission line. Graphed as power. When it is determined that the transmission plan power does not exceed the transmittable power (surplus power), the transmission plan creation means 10 approves the time variation characteristics of the transmission plan power, creates it as a transmission plan, The time variation characteristic of the planned power transmission is transmitted to the operator 5.
[0043]
Alternatively, the power transmission plan creation means 10 can automatically set a value that is less than or equal to a predetermined value from the derived surplus power (power that can be transmitted) as the power transmission plan power. For example, a power value smaller by 300 (kW) than surplus power (power that can be transmitted) can be automatically set as transmission planned power. In that case, a power value smaller by 300 (kW) than the calculated surplus power (power that can be transmitted) is displayed in the numerical value input field 26 and displayed in a graph. Can be changed by an operator of the power transmission plan creation system 4.
[0044]
As described above, even if it is difficult to estimate the transmission power from the power generation system 3 due to a large amount of power demand in the power generation system 3, the transmission plan creation method according to the present invention should be adopted. Thus, it is possible to derive the time variation characteristic of the power that can be transmitted with high accuracy. As a result, when the electric utility who has received this transmission plan makes a power supply contract with the consumer 6, it refers to the transmission plan and transmits the transmission power from the power generation system 3 and the power demand of the consumer 6. Can be adjusted so as to be consistent with each other to achieve the same amount control simultaneously.
[0045]
<Another embodiment>
<1>
The power generation system 3 illustrated in FIG. 1 includes a power generation facility 1 and a power consuming device 2 that receives power necessary for operation from the power generation facility. As another embodiment, the power generation system 30 illustrated in FIG. In addition to the power generation facility 1 as a dedicated power generation facility, a combined heat and power supply facility 11 that generates heat and electricity together and can be supplied to other devices, and a thermoelectric that generates power using waste heat in the power generation system 30 It comprises a conversion facility 13 and one or a plurality of heat consuming devices 12 that are operated using the heat received from the combined heat and power facility 11. In addition, since the description about the electric power company 5 and the customer 6 which were illustrated in FIG. 1 is the same, it abbreviate | omits from FIG.
[0046]
Similarly to the case where the power consuming device 2 is classified into a plurality of types in the above-described embodiment, the heat consuming device 12 is also classified into a plurality of types. Here, as described later, the first heat consuming device 12a and the second heat consuming device. 12b and the third heat consuming device 12c. Since the first heat consuming device 12a is operated in a steady pattern, the time variation characteristic of heat demand is known, or the time variation characteristic of heat demand can be estimated with very high accuracy (heat Demand decision process). Since the second heat consuming device 12b and the third heat consuming device 12c are not operated in a steady pattern, the time variation characteristics of heat demand are unknown, but are operated in connection with the occurrence of a specific event. Therefore, it is possible to estimate the time fluctuation characteristics of the heat demand with reference to the event execution schedule (heat demand determination step).
[0047]
Examples of the event include “gas production” and the like. A heat consuming apparatus for heating and vaporizing liquid LNG based on an event (production plan) such as what kind of gas is produced and how much. Information on the operation schedule of 12c is determined, and the time fluctuation characteristics of the heat demand can be estimated with reference to the information on the operation schedule. Alternatively, when abstract information such as a production plan is not collected, but information related to the operation schedule can be collected, the heat demand time is referred to the operation schedule of the heat consuming apparatus 12b. Variability characteristics are estimated.
[0048]
Here, when a certain event occurs, it is known to the power transmission plan creation system 40 which heat consuming device (s) among all the heat consuming devices is operated when the event occurs. This also applies to the power consuming device 2 as described above. When each event occurs, the operation target device (single or plural power consuming devices or single or plural heat consumptions) for the implementation of the event. It is assumed that a device or a combination thereof is predetermined.
[0049]
Therefore, in the power transmission plan creation system 40, the operation schedule determination means 7 that collects information related to the production plan of the third heat consuming device 12c and determines the operation schedule by the third heat consuming device 12c, and the second heat consuming device. 12b and the operation schedule determination means 7 are collected, and the heat demand determination means 14 which collects the time fluctuation characteristic of the heat demand by the 2nd heat consumption apparatus 12b and the 3rd heat consumption apparatus 12c is collected. . As described above with reference to FIG. 1, the operation schedule determination means 7 collects information related to the production plan of the third power consuming device 2c and determines the operation schedule by the third power consuming device 2c. The power demand determination means 8 collects information on the operation schedule from the second power consumption device 2b and the operation schedule determination means 7, and the time fluctuation characteristics of the power demand by the second power consumption device 2b and the third power consumption device 2c. To decide.
[0050]
In FIG. 9, the time variation characteristics of the heat demand, the operation schedule, and the production plan are transmitted from each of the first heat consuming device 12a, the second heat consuming device 12b, and the third heat consuming device 12c to the power transmission plan creating system 40. For convenience, the information on the power is transmitted to each of the first power consuming device 2a, the second power consuming device 2b, and the third power consuming device 2c from the power transmission planning system 40. Although the information regarding the characteristics, the operation schedule, and the production plan is illustrated for convenience, an apparatus for managing the information is actually provided separately and automatically used in the power transmission plan creation system 40. It is assumed that it is in a possible state.
[0051]
Next, information (in other words, the amount of heat supplied from the combined heat and power supply facility 11 to the heat consuming device 12) regarding the time fluctuation characteristics of the heat demand by the heat consuming device 12 (12a to 12c) is transmitted to the waste heat amount determining means 15, The amount of heat that has not been consumed by the heat consuming device 12 is determined as a time variation characteristic of the amount of waste heat in the power generation system 30 that can be used in the thermoelectric conversion operation by the thermoelectric conversion facility 13 (waste heat amount determination step). If there is a separate device for generating heat in the power generation system 30, the time variation characteristic of the waste heat amount is determined in consideration of the time variation characteristic of the heat generation amount.
[0052]
In addition, information related to the time variation characteristic of the heat demand by the heat consuming device 12 (12a to 12c) is also transmitted to the generated power determining means 16, so that heat is supplied corresponding to the time variation characteristic of the heat demand. The time variation characteristics of the electric power generated when the combined heat and power supply facility 11 is operated are determined. Furthermore, the information on the temporal variation characteristic of the waste heat amount in the power generation system 30 that can be used for the thermoelectric conversion operation by the thermoelectric conversion facility 13 is transmitted to the generated power determination means 16, and the thermoelectric conversion is performed using the waste heat amount. A time variation characteristic of electric power generated when the facility 13 is operated is determined.
[0053]
Therefore, the surplus power estimation means 9 includes information on the time fluctuation characteristics of power demand by the power consuming devices 2 (2a to 2c), generated power (power generated by the power generation facility 1 dedicated to power generation, and power generated by the combined heat and power generation facility 11). And information on the temporal variation characteristics of the sum of the power generated by the thermoelectric conversion facility 13). Although the power generated by the power generation facility 1 is substantially constant, more accurate power generation can be estimated in consideration of the predicted temperature (because the fuel concentration changes with the outside temperature and affects the power generated). As a result, the surplus power estimation means 9 refers to the time variation characteristic of the generated power and the time variation characteristic of the power demand by the power consuming device 2 derived in the same manner as in the above-described embodiment. The time fluctuation characteristic of surplus power can be estimated.
[0054]
Information on the temporal fluctuation characteristics of surplus power is transmitted to the transmission plan creation means 10, which transmits the transmission plan of the transmission power that can be transmitted to the consumer 6 (not shown in FIG. 9) A fluctuation characteristic) is created based on the surplus power, and the plan is transmitted to the electric utility 5 (not shown in FIG. 9). Here, when it is necessary to create a transmission plan every 30 minutes (time fluctuation characteristics of transmission power every 30 minutes), at least every 30 minutes using the operation schedule of the heat consuming apparatus 2 every 30 minutes It is preferable to determine the time fluctuation characteristics of the power demand every 30 minutes using the time fluctuation characteristics of the heat demand and the operation schedule of the power consuming apparatus 2 at least every 30 minutes.
[0055]
A specific example of another embodiment will be described below.
As an example of the power generation system 30, as shown in FIG. 10, a facility including an LNG receiving / storage facility that receives and stores LNG from an LNG (liquefied natural gas) ship and a gas production facility is taken as an example. Each of the LNG receiving / storage facility and gas production facility includes various power consuming devices 2 such as a motor, a pump, a measuring device, an air conditioning device, an office device, and a lighting device, and a heating device and an air conditioner for heating and vaporizing the LNG. A heat consuming device 12 such as a device (for example, a gas heat pump: GHP) is provided. Therefore, in addition to the power generation facility 1 dedicated to power generation, a combined heat and power facility (cogeneration facility) 11 that supplies heat and electricity together is provided. In addition, a thermoelectric conversion facility (for example, a steam turbine facility) 13 that can operate using waste heat from the LNG receiving / storage facility and the gas production facility is also provided. That is, the power generation system 30 includes the power generation facility 1, the cogeneration facility 11, the thermoelectric conversion facility 13, the power consumption device 2, and the heat consumption device 12.
[0056]
First, in the same manner as described with reference to FIGS. 3 to 5, the determination of the time fluctuation characteristics of the power demand in each power consuming apparatus 2 is performed in the power transmission plan creation system 40 (power demand determination step), The determined time fluctuation characteristic of the power demand is transmitted to the surplus power estimating means. Therefore, if the time variation characteristic of the generated power of the power generation system 30 is determined, the time variation characteristic of the surplus power can also be estimated. The time variation characteristic of the generated power of the power generation system 30 is the sum of the generated power of the power generation facility 1, the generated power of the combined heat and power supply facility 11, and the generated power of the thermoelectric conversion facility 13. It is required to accurately determine the fluctuation characteristics.
[0057]
When an event of “gas production” similar to that exemplified when determining the time fluctuation characteristics of the power demand of the power consuming device 2 occurs, information related to the production plan of the gas that is the product is known. The operation schedule determination means 7 refers to the information on the production plan, and among all the heat consuming devices, which heat consuming device (one or more) performs the operation based on what operating schedule (event execution schedule). You can decide what to do. Furthermore, the heat demand determination means 14 can determine the time fluctuation characteristic of the heat demand of the heat consuming apparatus to be operated with reference to the information related to the operation schedule. Specifically, since the amount of heat required to heat and vaporize LNG is estimated from the amount of gas produced, the operation schedule of the heating device (an example of the heat consuming device 12c) is first determined, and the operation schedule is The time fluctuation characteristic of the heat demand is determined with reference to the heat demand determination process. When an event execution schedule (operation schedule of the heat consuming apparatus 12b) is given instead of abstract information such as "production plan", the heat demand determining means 14 follows the operation schedule and the heat consuming apparatus The time fluctuation characteristic of the heat demand of 12b is determined (heat demand determination process). In addition, when an air conditioner using GHP or the like (an example of the heat consuming device 12a) is operated in a steady pattern (predetermined operation pattern), the time variation pattern of heat demand is easily determined from the operation pattern. Is done.
[0058]
Next, the information regarding the time fluctuation characteristic of the heat demand determined as described above is transmitted to the generated power determination means 16 and the waste heat amount determination means 15. In the waste heat amount determination means 15, the above-described waste heat amount determination step is executed, and the time fluctuation characteristics of the waste heat amount available in the thermoelectric conversion facility 13 are determined. As a result, the time variation characteristic of the generated power by the combined heat and power generation facility 11 and the time variation characteristic of the generated power by the thermoelectric conversion facility 13 are determined. Therefore, the surplus power estimation means 9 determines the total time fluctuation characteristics of the power generated by the power generation facility 1 dedicated to power generation, the power generated by the combined heat and power supply facility 11, and the power generated by the thermoelectric conversion facility 13, and the above-mentioned power With reference to the time fluctuation characteristic of the power demand in each power consuming apparatus 2 derived in the demand determination step, the time fluctuation characteristic of the surplus power in the power generation system 30 is estimated. Thereafter, information on the temporal fluctuation characteristics of surplus power is transmitted to the transmission plan creation means 10, which transmits the transmission power transmission plan (transmission power) that can be transmitted to the customer 6 (not shown in FIG. 9). (Time fluctuation characteristic) of the power generation is generated based on the surplus power, and the plan is transmitted to the electric utility 5 (not shown in FIG. 9).
[0059]
<2>
Next, a power transmission plan creation program for executing each process of the power transmission plan creation method according to the present invention will be described.
The above-described power transmission plan creation method is a power transmission plan creation program capable of executing the power demand determination step, the surplus power estimation step, and the power transmission plan creation step, or the heat demand determination step in addition to the above steps. And it implement | achieves by starting the power transmission plan preparation program which can perform at least one of the said waste heat amount determination process on the power transmission plan preparation system 4 (or power transmission plan preparation system 40). The power transmission plan creation system 4 (or the power transmission plan creation system 40) can be realized by using an information processing apparatus including a calculation processing unit capable of executing a predetermined program, a storage unit such as a memory and a hard disk drive, and the like. A typical computer can also be used. In order to execute the above-described steps, a program provided as a basic function by an operating system or the like installed in the transmission plan creation system 4 (or transmission plan creation system 40) or an existing program is used. Sometimes. When the power transmission plan creation system 4 (or the power transmission plan creation system 40) is constructed by one or more computers, a part or all of the power transmission plan creation program according to the present invention is installed in each computer. In some cases, each process is executed on a separate computer.
[0060]
<3>
Next, a computer-readable recording medium storing the above power transmission plan creation program will be described.
In order to execute a transmission plan creation program for causing a computer (the transmission plan creation system 4 (or transmission plan creation system 40)) to execute each step of the transmission plan creation method according to the present invention, the transmission plan creation program is The computer (the power transmission plan creation system 4 (or the power transmission plan creation system 40)) needs to be stored in a recording medium (for example, a hard disk or a CD-ROM) that can be read. For this purpose, the power transmission plan creation program may be downloaded to the hard disk drive, or a CD-ROM in which the power transmission plan creation program is recorded may be installed so that the computer can read it.
[0061]
Here, each process described above may be realized by using a program provided as a basic function of the computer (power transmission plan creation system 4 (or power transmission plan creation system 40)) or an existing program. Since these programs are not necessarily installed in a general-purpose computer, some or all of these programs may be recorded on the recording medium. Note that the recording medium is not necessarily a physically single medium. For example, even if the program is distributed and arranged on a plurality of CD-ROMs or recording media managed by other information processing apparatuses connected to the power transmission plan creation system 4 (or the power transmission plan creation system 40). I do not care.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing a flow of information and electric power centering on a power transmission plan creation system.
FIG. 2 is a schematic diagram of a specific example of a power generation system.
FIG. 3 is a diagram illustrating a screen example of a display device of a power transmission plan creation system.
FIG. 4 is a diagram illustrating a screen example of a display device of a power transmission plan creation system.
FIG. 5 is a diagram illustrating a screen example of a display device of a power transmission plan creation system.
FIG. 6 is a diagram illustrating a screen example of a display device of the power transmission plan creation system.
FIG. 7 is a diagram illustrating a screen example of a display device of the power transmission plan creation system.
FIG. 8 is a diagram illustrating a screen example of a display device of the power transmission plan creation system.
FIG. 9 is another schematic diagram showing the flow of information and power, centering on the power transmission plan creation system.
FIG. 10 is a schematic view of another specific example of the power generation system.
[Explanation of symbols]
1 Power generation facilities
2 Power consumption device
3 Power generation system
4 Transmission planning system
5 Electricity companies
6 consumers
7 Operation schedule decision means
8 Electricity demand determination means
9 Surplus power estimation means
10 Transmission plan creation means
11 Cogeneration facilities
12 Heat-consuming device
13 Thermoelectric conversion equipment
14 Heat demand determination means
15 Waste heat amount determination means
16 Generated power determination means
20 Electricity demand column
21 Numerical input field
22 Electricity demand column
23 Numeric input field
24 Electricity demand column
25 Numeric input field
26 Numerical input field
30 Power generation system
40 Power transmission planning system

Claims (7)

A power transmission plan creation method for creating a power transmission plan from a power generation system to a consumer comprising one or a plurality of power generation facilities and a plurality of power consuming devices that receive power necessary for operation from the one or a plurality of power generation facilities. ,
The plurality of power consuming devices are classified into a first device that is operated in a steady pattern and a second device that is operated in connection with the occurrence of a specific event, and each of the plurality of power consuming devices. A power demand determination process for determining the time fluctuation characteristics of the power demand;
A surplus power estimation step of estimating a time variation characteristic of surplus power in the power generation system with reference to the time variation characteristic of the power demand and the time variation characteristic of the generated power by the one or more power generation facilities,
A transmission plan creation method including a transmission plan creation step of creating a transmission plan of transmission power that can be transmitted to the consumer based on the surplus power estimated in the surplus power estimation step. The power transmission plan creation method according to claim 1, wherein a time variation characteristic of the power demand of the second device is determined based on an implementation schedule of the event. The power generation system includes a combined heat and power facility that generates heat and electricity as part or all of the power generation facility, and one or more heat consuming devices that operate using heat received from the combined heat and power facility. Prepared
A heat demand determining step for determining a time variation characteristic of each of the heat demands of the one or more heat consuming devices;
Time variation of electric power generated when the combined heat and power facility is operated such that the time variation characteristic of the generated power by the one or more power generation facilities supplies heat corresponding to the time variation characteristic of the heat demand The power transmission plan creation method according to claim 1 or 2, which is determined with reference to characteristics. In the heat demand determination step, the one or more heat consuming devices are classified into a third device operated in a steady pattern and a fourth device operated in connection with the occurrence of a specific event, The power transmission plan creation method according to claim 3, wherein a time variation characteristic of the heat demand is determined. The power transmission plan creation method according to claim 4, wherein the time fluctuation characteristic of the heat demand of the fourth device is determined based on an implementation schedule of the event. The one or more power generation facilities include a thermoelectric conversion facility that generates power using waste heat in the power generation system,
A waste heat amount determination step for determining a time variation characteristic of the waste heat amount available to the thermoelectric conversion facility,
The time variation characteristic of the generated power by the one or more power generation facilities is the time variation characteristic of the electric power generated when the thermoelectric conversion facility is operated using the waste heat amount determined in the waste heat amount determination step. The power transmission plan creation method according to any one of claims 1 to 5, which is determined by reference. A power transmission plan creation program for causing a computer to execute each step of the power transmission plan creation method according to any one of claims 1 to 6.

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