JP4856219B2 - Mobile control device - Google Patents

Description

  The present invention relates to a moving body control apparatus.

  For example, there are various types of running modes of a moving body such as a railway vehicle, such as power running, running, and braking (regeneration).

  When the moving body travels by electric energy (electric power), the amount of electric energy required for traveling varies depending on the traveling mode.

  In addition, the traveling resistance of the moving body changes depending on terrain conditions such as a gradient, and the amount of electrical energy required for traveling changes even when performing constant speed traveling.

  By providing the moving body with a regenerative brake, electric energy can be generated during braking. The electric energy generated by the regenerative brake may be stored in an electric energy storage device or may be consumed by resistance or the like.

  The following Patent Document 1 discloses a technique for determining a usage ratio between an engine and an electrical energy storage device when a railway or the like travels along a route having a predetermined travel pattern along the travel pattern. Patent Document 1 discloses a technique for switching the operation mode prepared in advance at the time of delay to recover the delay.

  In the following Patent Documents 2 and 3, a method of using an electric energy generator and an electric energy storage device according to a gradient condition during traveling is disclosed.

  Patent Document 4 below discloses a technique for switching a traveling mode depending on a vehicle position during traveling.

JP 2003-134604 A JP 2001-352607 A JP 2002-199509 A Japanese Patent Laid-Open No. 11-111472

  In some cases, the amount of power generated by the electrical energy generator is set to a predetermined amount in advance. For example, in an electric energy generating device that generates electric energy based on some kind of fuel, such as a fuel cell, the total power generation amount is limited to the power generation amount until the fuel runs out unless fuel is replenished.

  In Patent Documents 1 to 4 described above, an electric energy generation device and an electric energy storage device are mounted on a moving body, and a position where electric energy is generated and a position where electric energy is stored are determined according to topographic conditions.

  When the total amount of power generated by the electrical energy generator is limited, it is desirable to reduce the chance of generating electrical energy by the electrical energy generator and to keep the electrical energy generator usable. .

  However, in Patent Documents 1 to 4, no consideration is given to minimizing the total amount of electric energy generated.

  For this reason, for example, when the electric energy generator generates electric energy based on the fuel, the fuel may be wasted.

  In addition, in order to prevent the amount of electric energy generated by the electric energy generating device (the amount of electric power) from exceeding the amount of electric energy that can be stored in the electric energy storage device, the generated electric energy is not stored. When the rated capacity of the electric energy storage device is increased, the weight and size of the electric energy storage device increase, and the loading capacity of the moving body increases.

  Further, if the rated capacity of the electric energy storage device is too small, it is necessary to enlarge the electric energy generation device, the weight and size of the electric energy generation device increase, and the loading capacity of the moving body increases.

  When the loading capacity of the moving body increases, it becomes difficult to efficiently travel the moving body.

  The present invention has been made in view of the above circumstances, and a mobile control device that optimizes the amount of electrical energy generated by an electrical energy generator and the capacity of electrical energy stored in the electrical energy storage device. The purpose is to provide.

  In the moving body control device that controls the moving body including the electric energy generation device and the electric energy storage device, the above problem is based on the operation data that represents the relationship between each position of the moving body and the driving mode. For each position of the moving body, a total generation amount of electric energy calculated by an evaluation function for obtaining a total amount of electric energy generation of the electric energy generation device in a plurality of sections is within a predetermined generation allowable range including a minimum value. A determination means for determining an electric energy generation amount of the electric energy generation device and a discharge amount of the electric energy storage device; a means for detecting the position of the moving body; and the electric energy of the electric energy generation device with respect to the detected position of the moving body Means for requesting the electrical energy generator to generate electrical energy according to the amount generated; Accordance discharge capacity of the electric energy storage device for the position of the moving body can be solved by having a means for requesting a discharge of electrical energy into electrical energy storage device.

  An object of the present invention is to provide a moving body control device that controls a moving body that includes an electric energy generation device and an electric energy storage device, and that detects a position of the moving body and an electric energy storage amount of the electric energy storage device. The predetermined amount of electric energy generated by the electric energy generating device includes a minimum value based on the means, the traveling line of the moving body, the traveling schedule of the moving body, the detected position of the moving body, and the accumulated amount of electric energy. According to the determination result by the determination means, the determination means for determining the electric energy generation amount of the electric energy generation device and the discharge amount of the electric energy storage device so that the moving body satisfies the travel schedule while being within the allowable range, The means for requesting the electrical energy generator to generate electrical energy and the decision result by the decision means Therefore, it can be solved by having a means for requesting a discharge of electrical energy into electrical energy storage device.

  In the present invention, the amount of electrical energy generated by the electrical energy generator and the capacity of electrical energy stored in the electrical energy storage device can be optimized.

The block diagram which shows an example of a structure of the mobile body control apparatus which concerns on the 1st Embodiment of this invention. The figure which shows an example of the content of topographical data. The figure which shows an example of the content of position speed data. The figure which shows an example of the content of the driving | running data created based on topographical data and position speed data. The figure which shows an example of a structure of a power management part. The figure which shows an example of power management data. The block diagram which shows an example of a structure of the mobile body control apparatus which concerns on the 2nd Embodiment of this invention. The block diagram which shows an example of a structure of the mobile body control apparatus which concerns on the 3rd Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following drawings, the same elements are denoted by the same reference numerals, description thereof is omitted, and only different portions will be described in detail.

(First embodiment)
In the present embodiment, for example, an electric energy generation device and an electric energy storage device that have a certain degree of restriction or restriction on the total power generation amount, such as power generation based on fuel, are provided, and the power generation amount of the electric energy generation device is suppressed. A moving body control device that realizes efficient use of electric energy will be described.

  In the present embodiment, the case where the moving body is a railway vehicle will be described as an example, but another moving body such as an automobile or a new transportation vehicle may be used.

  FIG. 1 is a block diagram showing an example of the configuration of the mobile control device according to the present embodiment.

  The moving body 1 includes current collectors 2 and 3, a voltage converter 4, an AC / DC converter 5, a bus 6, a DC / AC converter 7, a drive device 8, a drive control device 9, a fuel storage unit 10, and an electric energy generator. 11, generation control device 12, electrical energy storage device 13, storage control device 14, transmission line 15, recording unit 16, moving body control device 17, and switch 18.

  The current collector 2 receives electrical energy generated when the regenerative brake of the moving body 1 is used from the regenerative brake. In addition, the current collector 2 receives electrical energy from an electrical energy generator that generates power even when there is no fuel such as a solar cell provided in the moving body 1.

  Then, the current collector 2 provides the received electrical energy to at least one of the DC / AC converter 7 and the electrical energy storage device 13 via the bus 6.

  The current collector 3 is, for example, a pantograph or a third rail, and receives current energy. When the current collector 3 is a pantograph, the current collector 3 receives an alternating current from an overhead wire.

  The voltage converter 4 converts the alternating current received by the current collector 3 into a predetermined voltage value.

  The AC / DC converter 5 converts the AC current converted by the voltage converter 4 into a DC current, and provides it to at least one of the DC / AC converter 7 and the electrical energy storage device 13 via the bus 6.

  The DC / AC converter 7 receives a DC current from the AC / DC converter 5, the electrical energy generator 11, and the electrical energy storage device 13 via the bus 6, converts the DC current into an AC current, and provides the drive device 8 with the DC current. .

  The drive device 8 receives electrical energy from the DC / AC converter 7 and performs the traveling operation of the moving body 1 using the received electrical energy in accordance with a command from the drive control device 9. The driving mode of the drive device 8 includes, for example, power running, running, and brake running. A plurality of the driving devices 8 may be provided in the moving body 1.

  The drive control device 9 is provided for each drive device 8. The drive control device 9 receives a powering command, a running command, a brake travel command, and a speed command for causing the vehicle speed to follow the target speed from the moving body control device 17 via the transmission line 15 and travel operation according to the command. Is executed by the drive device 8. The drive control device 9 may determine the current value of the drive device 8 in accordance with the accepted command.

  The fuel storage unit 10 stores the fuel necessary for the electric energy generator 11 to generate power.

  The electrical energy generation device 11 generates power using the fuel stored in the fuel storage unit 10 in accordance with a command from the generation control device 12. As the electric energy generator 11, for example, a fuel cell that generates power using hydrogen as a fuel is used. A plurality of electric energy generators 11 may be provided in the moving body 1.

  The generation control device 12 is provided for each electric energy generation device 11. The generation control device 12 receives a power generation command and a power generation stop command from the mobile control device 17 via the transmission line 15.

  When the generation control device 12 receives a power generation command, the generation control device 12 causes the electric energy generation device 11 to generate power in response to the power generation command.

  On the other hand, when the generation control device 12 receives a power generation stop command, the generation control device 12 causes the electrical energy generation device 11 to stop power generation in response to the power generation stop command.

  Furthermore, the generation control device 12 obtains the amount of power (for example, maximum output) generated by the electrical energy generation device 11 and provides the generated amount data indicating the amount of power to the mobile control device 17 via the transmission line 15.

  The electrical energy storage device 13 stores at least one of the direct current received from the AC / DC converter 5 and the current received from the electrical energy generation device 11 according to the control by the storage control device 14. Alternatively, the electrical energy storage device 13 discharges the stored electrical energy and provides it to the DC / AC converter 7 in accordance with control by the storage control device 14. A plurality of electric energy storage devices 13 may be provided in the moving body 1.

  The storage control device 14 is provided for each electrical energy storage device 13. The accumulation control device 14 receives a charge command or a discharge command from the mobile control device 17 via the transmission line 15.

  When the storage control device 14 receives a charge command from the mobile control device 17, the storage control device 14 causes the electrical energy storage device 13 to perform charging in accordance with the charge command.

  On the other hand, when the storage control device 14 receives a discharge command from the moving body control device 17, the storage control device 14 causes the electrical energy storage device 13 to execute a discharge in response to the discharge command.

  Further, the storage control device 14 obtains the amount of power stored in the electrical energy storage device 13 and provides stored amount data indicating this power amount to the mobile control device 17 via the transmission line 15.

  The recording unit 16 records terrain data 19, position / velocity data 20, and allowable range data 21.

  The terrain data 19 represents the terrain of the traveling track of the moving body 1. For example, the terrain data 19 represents the relationship between the position of the traveling track and the altitude.

  The position speed data 20 represents the relationship between each position and speed of the traveling track of the moving body 1.

  The allowable range data 21 includes the amount of electric energy that is allowed to be generated by the electric energy generator 11 (electric energy generation allowable range) and the amount of electric energy that can be stored by the electric energy storage device 13 (electric energy storage allowable range). Represents. The allowable generation range indicated by the allowable range data 21 is set at a level as low as possible. This is because as the electric energy generation allowable range is set to be low, the amount of electric energy generated decreases and the consumption of fuel can be reduced.

  The mobile body control device 17 includes an operation data creation unit 22, a generation amount reception unit 23, an accumulation amount reception unit 24, a power management unit 25, a position detection unit 26, a speed detection unit 27, a travel control unit 28, and an electric energy reception unit 29. The electric energy providing unit 30 and the command receiving unit 31 are provided.

  The driving data creation unit 22 creates driving data representing the relationship between each position of the moving body 1 and the travel mode based on the topographic data 19 and the position / speed data 20 recorded in the recording unit 16.

  FIG. 2 is a diagram showing an example of the contents of the terrain data 19.

  In the terrain data 19, the relationship between each position and its altitude when the moving body 1 moves from the A station to the D station along the traveling track is represented.

  FIG. 3 is a diagram illustrating an example of the contents of the position / velocity data 20.

  The position speed data 20 represents the relationship between each position and the speed when the moving body 1 moves from the A station to the D station along the travel line.

  FIG. 4 is a diagram showing an example of the contents of the operation data created based on the topographic data 19 and the position / velocity data 20.

  The operation data shown in FIG. 4 represents the travel modes at each position when the moving body 1 moves from the A station to the D station along the travel line.

  The driving data creation unit 22 determines a driving mode for realizing the speed represented by the position speed data 20 at each position moving from the A station to the D station, and creates driving data.

  For example, power running is determined at a certain up position. Further, in a certain downward position, the running or the brake traveling that can realize the speed indicated by the position speed data 20 is determined. In other down positions, powering may be determined in order to realize the speed represented by the position speed data 20.

  The operation data creation unit 22 provides the operation data to the power management unit 25 via the transmission line 15.

  The generation amount reception unit 23 receives generation amount data from the generation control device 12 via the transmission line 15 and provides the received generation amount data to the power management unit 25 via the transmission line 15.

  The storage amount receiving unit 24 receives storage amount data from the storage control device 14 via the transmission line 15 and provides the received storage amount data to the power management unit 25 via the transmission line 15.

  The position detection unit 26 detects the travel position of the moving body 1 and provides position data indicating the travel position to the power management unit 25 and the travel control unit 28 via the transmission line 15.

  As shown in FIG. 5, the power management unit 25 includes a determination unit 25a, a first request unit 25b, and a second request unit 25c.

  In a normal state where an alternating current is received from the overhead line to the current collector 3, the determination unit 25 a determines that the electric energy generation device 11 stops power generation and the electric energy storage device 13 is charged.

  As a result, the first request unit 25b provides a power generation stop command to the generation control device 12 via the transmission line 15, and the second request unit 25c provides a charge command to the storage control device 14 via the transmission line 15. To do.

  Thereby, in the normal state, the moving body 1 travels with electric energy based on the alternating current from the overhead line, and also stores the electric energy based on the alternating current from the overhead line in the electrical energy storage device 13.

  The power management unit 25 performs the following operation in a state where an alternating current is not received from the overhead line to the current collector 3, for example, when a power failure occurs.

  The determination unit 25 a of the power management unit 25 receives operation data, generation amount data, accumulation amount data, and position data, and reads the allowable range data 21 of the recording unit 16 via the transmission line 15.

  Based on the operation data, the determination unit 25a determines that the total amount of electric energy generated by the electric energy generator 11 is a predetermined generation allowable range indicated by the allowable range data 21, and the electric energy storage amount of the electric energy storage device 13 is the allowable range data. The electric energy generation amount by the electric energy generation device 11 and the electric energy accumulation amount (discharge amount or charge amount) of the electric energy storage device 13 are set for each position of the moving body 1 so that the predetermined accumulation allowable range indicated by 21 is obtained. ) And create power management data.

  FIG. 6 is a diagram illustrating an example of power management data. FIG. 6 shows an example of power management data determined for the operation data shown in FIG.

  For example, the determination unit 25a determines that the current received by the current collector 2 such as the electrical energy generated by the regenerative braking is stored in the electrical energy storage device 13 when the travel mode is brake travel and travel.

  Further, the determination unit 25a determines that the electrical energy stored in the electrical energy storage device 13 is discharged when the running mode is power running. As a result, the electric energy stored during braking and running is used in subsequent power running.

  In addition, when the power running continues for a long time and the accumulated amount indicated by the accumulated amount data is equal to or less than a predetermined value, the determining unit 25a determines that the total generated electric energy is in addition to the electric energy accumulated in the electric energy accumulating device 13. It is determined that the electric energy generation device 11 performs power generation so that the predetermined generation allowable range and the predetermined storage allowable range indicated by the electric energy storage amount of the electric energy storage device 13 are set. The determination unit 25a stores the electric energy generated by the electric energy generation device 11 when the electric energy generation amount by the electric energy generation device 11 is less than the amount of electric energy necessary for the traveling of the moving body 1. It may be determined that the electrical energy is stored in the device 13 and then the electrical energy is generated by the electrical energy generator 11 and the electrical energy stored in the electrical energy storage device 13 is discharged.

  The determination unit 25a monitors the generation amount of electric energy indicated by the generation amount data so as not to exceed a predetermined range.

  Further, the determination unit 25a determines that the generation of the electric energy by the electric energy generation device 11 is stopped when the electric energy storage amount indicated by the storage amount data exceeds the allowable storage amount of the electric energy storage device 13. .

  Based on the determination result of the determination unit 25a described above and the position indicated by the position data, the first request unit 25b of the power management unit 25 has electric energy when it is located at a point where the mobile body 1 travels over a predetermined interval by power running. A power generation command is generated via the transmission line 15 such that the total amount of electric energy generated by the generator 11 falls within a predetermined allowable generation range and the predetermined allowable storage range indicated by the electric energy storage amount of the electric energy storage device 13. Provided to the controller 12.

  On the other hand, the first request unit 25 b provides a generation stop command to the generation control device 12 via the transmission line 15 at the time when the generation command is not provided.

  Further, the first request unit 25b provides the generation control device 12 with a power generation stop command when the electrical energy storage amount of the electrical energy storage device 13 exceeds the allowable storage amount.

  The second request unit 25c of the power management unit 25 accumulates the charging command via the transmission line 15 at the position where the vehicle travels in the brake travel and the main line based on the determination result of the determination unit 25a and the position indicated by the position data. Provided to the controller 14.

  On the other hand, at a position where the vehicle travels by power running, the second request unit 25 c provides a discharge command to the accumulation control device 14 via the transmission line 15.

  The speed detector 27 detects the speed of the moving body 1 and provides speed data indicating the speed to the travel controller 28 via the transmission line 15.

  The travel control unit 28 receives the position data from the position detection unit 26 and the speed data from the speed detection unit 27, and reads the position / speed data 20 of the recording unit 16 via the transmission line 15.

  The traveling control unit 28 provides a command for setting the speed indicated by the speed data to the speed indicated by the position speed data 20 to the drive control device 9 via the transmission line 15 at the position of the moving body 1 indicated by the position data. For example, the traveling control unit 28 controls the speed of the moving body 1 so as to follow the target speed based on the traveling mode and the target speed of the moving body 1 or directly controls the current of the driving device 8 of the moving body 1. Determine the value.

  The command receiving unit 31 receives a charging command from the switch 18 or the centralized management system 32. Note that the switch 18 is provided in the moving body 1 and provides a charge command to the command receiving unit 31 when the switch 18 is turned on. The central management system 32 provides a charge command to the command receiving unit 31 when the operator of the central control room performs an operation to charge.

  When receiving a charging command from the switch 18 or the centralized management system 32, the command receiving unit 31 provides the charging command to the generation control device 12 via the transmission line 15 and stores the charging command to the storage control device 14 via the transmission line 15. I will provide a. Accordingly, it is possible to generate electrical energy by the electrical energy generator 11 and store the electrical energy generated by the electrical energy generator 11 in the electrical energy storage device 13.

  The electrical energy reception unit 29 provides the electrical energy received from the outside to the electrical energy storage device 13 via the bus 6 and stores it.

  The electrical energy provider 30 provides the electrical energy stored in the electrical energy storage device 13 to the outside.

  A specific example of the operation of the mobile control device 17 having the above configuration will be described below.

  The power management unit 25 sets a plurality of sections in the travel line, and sets the electric energy generation amount of the electric energy generator 11 as a reference in each section so that the total electric energy generation amount of the entire travel line is minimized. To decide. The power management unit 25 adjusts between the electric energy generation amount of the electric energy generation device 11 and the electric energy storage amount of the electric energy storage device 13, and determines the electric energy generation amount for the entire travel line. That is, the power management unit 25 determines the charge / discharge amount of the electrical energy storage device 13 depending on the amount of electrical energy generated by the electrical energy generation device 11.

  In addition, the power management unit 25 performs a process of automatically predicting / estimating / detecting a start-up torque shortage and a process of temporarily generating electric energy.

  In a case where a predetermined starting force cannot be obtained at the time of signal control or equipment abnormality / failure, or when the starting acceleration is insufficient with only the electric energy generation amount of the electric energy generating device 11, the power management unit 25 generates electric energy. The electrical energy generated by the device 11 is temporarily stored in the electrical energy storage device 13, and the electrical energy generated by the electrical energy generation device 11 after the storage and the electrical energy stored in the electrical energy storage device 13 are used for traveling. To decide.

  The electric energy providing unit 30 is used to move the electric energy stored in the electric energy storage device 13 to an external (for example, ground) storage device during a time zone when the moving body 1 does not travel such as at night. Thereby, the electrical energy stored in the electrical energy storage device 13 can be used for ground lighting or the like.

  The electric energy receiving unit 29 moves electric energy from an external storage device to the electric energy storage device 13 for use in traveling of the moving body 1.

  When the switch 18 is turned on and when it is set to be charged by the centralized management system that manages the operation of the mobile body 1, the command receiving unit 31 causes the electrical energy generator 11 to generate electrical energy at any time. Then, it is stored in the electrical energy storage device 13.

  Note that charging may be performed at a preset time, position, and speed.

  For example, when a failure occurs in a part of the moving body 1, the driving force may be insufficient when the moving body 1 temporarily stops at an unexpected position. In such a case, charging may be performed automatically.

  In the present embodiment described above, the electric energy generation amount and the electric energy accumulation amount can be appropriately determined, and the total energy amount for traveling can be reduced.

  In the present embodiment, the total amount of electric energy generated by the electric energy generating device 11 can be reduced, and the device scale of the electric energy generating device 11 and the capacity of the electric energy storage device 13 can be optimized. It is possible to achieve harmony between the scheduled operation and reduction of electric energy generation.

  In the present embodiment, the electrical energy utilization rate is improved, and the electrical energy generation device 11 and the electrical energy storage device 13 can be reduced in size.

The mobile body 1 can be stably supplied with electric power, can travel even during a power failure, and transportation by the mobile body 1 is stabilized.
In the present embodiment, the exchange of each data in the mobile body 1 may be realized by recording the data on a recording unit such as the recording unit 16 on the providing side and reading the data from the recording unit on the receiving side. . For example, the operation data creation unit 22 may record the operation data in the recording unit 16 via the transmission line 15, and the power management unit 25 may read the operation data from the recording unit 16 via the transmission line 15.

(Second Embodiment)
In the present embodiment, a mobile control device that accepts the power management data described in the first embodiment from the outside will be described.

  FIG. 7 is a block diagram showing an example of the configuration of the mobile control device according to the present embodiment.

  The mobile control device 33 according to the present embodiment deletes the operation data creation unit 22 of the mobile control device 17 according to the first embodiment, and the mobile control device according to the first embodiment. A power management unit 34 is provided instead of the 17 power management units 25.

  The other parts of the moving body control device 33 are the same as those of the moving body control device 17 according to the first embodiment, and therefore the illustration and description in FIG. 7 are omitted.

  Further, when the moving body 1 includes the moving body control device 33, the terrain data 19 and the allowable range data 21 may not be recorded in the recording unit 16 of the moving body 1.

  The power management unit 34 includes a data reception unit 35, a first request unit 25b, and a second request unit 25c.

  The data receiving unit 35 receives power management data from the outside before or during the movement of the mobile body 1. For example, the data receiving unit 35 receives power management data from the centralized management system 32 via the transmission line 15. In this case, the power management data is created by the centralized management system 32.

  In the power management data received by the data receiving unit 35 from the outside, various control parameter values are set.

  In the present embodiment, the configuration of the moving body control device 33 provided in the moving body 1 can be simplified, and the same effect as in the first embodiment can be obtained.

(Third embodiment)
In the present embodiment, a moving body control device that suppresses the amount of power generated by an electric energy generation device and realizes efficient use of electric energy based on a travel schedule will be described.

  FIG. 8 is a diagram illustrating an example of the configuration of the mobile control device according to the present embodiment.

  The moving body 36 according to the present embodiment differs from the moving body 1 described in the first embodiment in the recording contents of the recording unit 16.

  In addition, the moving body 36 includes a moving body control device 37 instead of the moving body control device 17 of the moving body 1 according to the first embodiment.

  In addition, since it is the same as that of the mobile body 1 which concerns on the said 1st Embodiment about other parts of the mobile body 36, illustration and description are abbreviate | omitted in FIG.

  The recording unit 16 of the moving body 36 includes terrain data 19, travel schedule data 38, characteristic data 39, and allowable range data 21.

  The travel schedule data 38 represents a travel schedule (travel plan) such as an operation schedule. For example, it represents the arrival time and the departure time at each station.

  The characteristic data 39 represents the generation characteristics of the electric energy by the electric energy generation device 11 and the electric energy storage characteristics of the electric energy storage device 13.

  The mobile control device 37 deletes the operation data creation unit 22 of the mobile control device 17 according to the first embodiment, and the power management unit 25 of the mobile control device 17 according to the first embodiment. In addition, a power management unit 40 and a travel control unit 41 are provided instead of the travel control unit 28.

  The other parts of the moving body control device 37 are the same as those of the moving body control device 17 according to the first embodiment, and therefore the illustration and description thereof in FIG. 7 are omitted.

  The power management unit 40 includes determination units 42, 25b, and 25c.

  In the normal state, the determination unit 42 determines that the power generation by the electric energy generation device 11 is stopped and the electric energy storage device 13 is charged.

  As a result, the first request unit 25b provides a power generation stop command to the generation control device 12 via the transmission line 15, and the second request unit 25c provides a charge command to the storage control device 14 via the transmission line 15. To do.

  The power management unit 40 performs the following operation in a state where the current collector 3 does not accept an alternating current from the overhead wire.

  The determination unit 42 of the power management unit 40 receives the generation amount data from the generation control device 12, the accumulation amount data from the accumulation control device 14, and the position data from the position detection unit 26, and the terrain data 19 of the recording unit 16, The travel schedule data 38, the characteristic data 39, and the allowable range data 21 are read out via the transmission line 15.

  The determination unit 42 determines the current amount of electric energy generated by the electric energy generator 11, the amount of electric energy stored in the current electric energy storage device 13, the current position of the moving body 36, the travel line of the moving body 36, and the moving body 36. Based on the travel schedule, the generation characteristics of the electric energy by the electric energy generation device 11, the electric energy storage characteristics of the electric energy storage device 13, the allowable generation range, and the allowable storage range, the electric energy generation amount and the electric energy by the electric energy generation device 11 The electrical energy storage amount (discharge amount or charge amount) of the storage device 13 is determined, and power management data is created.

  Specifically, the determination unit 42 determines that the total amount of electric energy generated by the electric energy generator 11 is within the allowable generation range, the electric energy storage amount of the electric energy storage device 13 is within the allowable storage range, and the moving body 36 sets the travel schedule. The electric energy generation amount of the electric energy generation device 11 and the electric energy storage amount (discharge amount or charge amount) of the electric energy storage device 13 at the present time are determined so as to satisfy, and power management data is created.

  The traveling control unit 41 reads the terrain data 19 and the traveling schedule data 38 from the recording unit 16 via the transmission line 15 and controls the speed of the moving body 36 at a target speed that satisfies the traveling schedule, or directly controls the moving body 36. The current value of the driving device 8 is determined.

  In the present embodiment described above, the traveling time of the moving body 36 can be ensured, electric energy can be used efficiently, and stable traveling can be realized.

(Fourth embodiment)
In the present embodiment, a specific example of the control method of the moving body control device will be described. The control method according to the present embodiment is effective for the mobile body control device 17 according to the first embodiment and the mobile body control device 33 according to the second embodiment.

  In the control method according to the present embodiment, a travel schedule that can be operated on a regular basis with one station as a unit is obtained by simulation.

  The amount of electric energy generated between the stations is calculated using an evaluation function so that the total amount of electric energy generated between the stations is minimized.

  Further, the amount of electric energy generated between the stations is determined so that the amount of electric energy stored in the electric energy storage device 13 falls within the allowable storage range.

  The arrival time of the next station is predicted by simulation, and the speed of the moving body 1 is determined so that the predicted arrival time does not exceed the arrival time defined in the travel schedule.

  The amount of electrical energy used by the drive device 8 at each time may be determined from the amount of electrical energy generated from the electrical energy generator 11 and the amount of electrical energy discharged from the electrical energy storage device 13. For example, in order to make the acceleration force of the moving body 1 constant, the electric energy usage amount of the driving device 8 may be determined based on the terrain data. Or the electric energy usage-amount of the drive device 8 may be made constant, and the acceleration speed of the mobile body 1 may change as a result.

  The above matters are considered between the stations on the running track, and the generation allowable range is set for each station on the entire running track.

  The permissible generation range for each station may be determined by an external device such as the centralized management system 32 and may be received by the mobile body 1 thereafter. In addition, the allowable generation range for each station may be determined on the moving body 1 in consideration of the traveling schedule of the day, the speed limit, and the like when the moving body 1 starts or leaves.

  That is, the allowable range data 21 may be determined within the moving body 1 or received from the outside.

  The electric energy amount used by the driving device 8 at each time point is determined by determining the electric energy accumulation amount necessary for traveling of the moving body 1 at that time point from the speed of the moving body 1 and actually calculating the accumulated amount necessary for traveling. When the amount of stored electric energy is not enough, the electric energy generating device 11 generates electric energy within the allowable generation range.

  As a result, the electric energy generation amount and the electric energy resource usage amount can be minimized and reduced, and the power generation capacity of the electric energy generation device 11 and the capacity of the electric energy storage device 13 can be optimized.

(Fifth embodiment)
In the present embodiment, a control method for a mobile body control device that dynamically determines an electrical energy generation amount and an electrical energy accumulation amount at each time point so that the mobile body satisfies a travel schedule will be described. The control method according to the present embodiment is effective for the mobile control device 37 according to the third embodiment.

  In the fourth embodiment, the electric energy generation amount is determined for each section in advance by simulation, but the electric energy generation amount and the electric energy accumulation amount at each time point are determined so as to satisfy the punctuality of the moving object. It is not taken into account.

  On the other hand, in this Embodiment, while considering the fixed property of a moving body, automatic train driving | running | working (ATO) is assumed and the power management and traveling control of a moving body are performed simultaneously. In addition, even if it does not perform an automatic train driving | operation, you may provide a driver | operator with a control result as driving assistance data.

  In the control method according to the present embodiment, the traveling control unit of the moving body starts at maximum acceleration after performing jerk control or minor control in consideration of the riding comfort when starting the moving body.

  When the electric energy is insufficient at the time of departure, the power management unit performs charging for a predetermined time or performs charging to such an extent that the insufficient electric energy is compensated, and then starts.

  The power management unit monitors the speed, position, amount of electric energy generated, amount of charge or discharge, and amount of stored electric energy in real time.

  Note that the power management unit may perform monitoring at regular intervals. The power management unit may perform monitoring at a preset timing, point, or condition (for example, when the maximum speed is reached).

  In addition, the power management unit estimates the arrival time of the next station based on various monitoring results, the travel line, and travel conditions (such as speed limit), so that the mobile object arrives on time according to the travel schedule. In addition, the amount of electric energy generated and the amount of electric energy charging / discharging up to the next station are determined using convergence calculation or the like.

  When it is determined that maintenance of punctuality is difficult, or when it is assumed that the mobile object arrives late, the power management unit removes the restriction due to the determined speed, and the electric energy generation amount in the section does not exceed the rated value Control is performed so that no delay occurs, such as setting the maximum output at.

  As a result, it is possible to systematically minimize the total amount of electrical energy generated using the electrical energy storage device, and to optimize the capacity of the electrical energy storage device. Then, it is possible to achieve harmony between the scheduled operation of the moving body and the suppression of the amount of electric energy generated by the electric energy generator.

  In each of the above embodiments, each component can be freely modified as long as the same operation can be realized. For example, the arrangement of each component may be changed, each component may be freely combined, and each component may be freely divided.

  For example, the moving body control device 17 may include a controller that combines the operation data creation unit 22, the power management unit 25, and the travel control unit 28.

  Operation data creation unit 22, power management units 25, 34, and 40, position detection unit 26, speed detection unit 27, travel control units 28 and 41, command reception unit 31, generation amount reception unit 23, accumulation in each of the above embodiments The function of the quantity receiving unit 24 may be realized by a computer that has read a program.

  In this case, the program can be written in a recording medium such as a magnetic disk (flexible disk, hard disk, etc.), an optical disk (CD-ROM, DVD, etc.), a semiconductor memory, etc., and applied to a computer.

  It is also possible to transmit this program via a communication medium and apply it to a computer. The computer reads the program and the operation is controlled by the program, whereby the operation data creation unit 22, the power management units 25, 34, and 40, the position detection unit 26, the speed detection unit 27, the travel control units 28 and 41, the command Functions as the reception unit 31, the generation amount reception unit 23, and the accumulation amount reception unit 24 are realized.

  INDUSTRIAL APPLICABILITY The present invention is effective in the field of controlling a mobile body that includes an electric energy generation device and an electric energy storage device that have a limited power generation amount.

  DESCRIPTION OF SYMBOLS 1,36 ... Mobile body, 2,3 ... Current collector, 4 ... Voltage converter, 5 ... AC-DC converter, 6 ... Bus-bar, 7 ... DC-AC converter, 8 ... Drive apparatus, 9 ... Drive control apparatus, DESCRIPTION OF SYMBOLS 10 ... Fuel storage part, 11 ... Electric energy generator, 12 ... Generation | occurrence | production control apparatus, 13 ... Electric energy storage device, 14 ... Storage control apparatus, 15 ... Transmission line, 16 ... Recording part, 17, 33, 37 ... Mobile Control device, 18 ... switch, 19 ... terrain data, 20 ... position speed data, 21 ... allowable range data, 22 ... operation data creation unit, 23 ... generated amount reception unit, 24 ... accumulated amount reception unit, 25, 34, 40 ... Power management unit, 25a, 42 ... Determination unit, 25b ... First request unit, 25c ... Second request unit, 26 ... Position detection unit, 27 ... Speed detection unit, 28 ... Travel control unit, 29 ... Electric energy reception unit , 30 ... Electric energy supply department, 31 ... Life Receiving unit, 32 ... centralized management system, 35 ... data receiving section, 38 ... travel schedule data, 39 ... characteristic data.

Claims (14)

In a mobile body control device that controls a mobile body comprising an electrical energy generation device and an electrical energy storage device,
Based on the operation data representing the relationship between each position of the moving body and the travel mode, the total electric energy calculated by an evaluation function for calculating the total amount of electric energy generated by the electric energy generating device in a plurality of sections of the travel line Determining means for determining an electric energy generation amount of the electric energy generation device and a discharge amount of the electric energy storage device with respect to each position of the moving body so that the generation amount falls within a predetermined allowable generation range including a minimum value; ,
Means for detecting the position of the moving body;
Means for requesting the electrical energy generator to generate electrical energy according to the amount of electrical energy generated by the electrical energy generator relative to the detected position of the moving body;
And a means for requesting the electric energy storage device to discharge electric energy in accordance with a discharge amount of the electric energy storage device relative to the detected position of the moving body. The moving body control device according to claim 1,
Based on the terrain data of the traveling track of the moving body and position / velocity data indicating the relationship between each position and speed of the moving body, a traveling mode at each position of the moving body is determined, and the operation data is created. Further comprising operation data creation means for
The determining means determines an electric energy generation amount of the electric energy generation device and a discharge amount of the electric energy storage device based on the operation data created by the operation data creation means. Body control device. The moving body control device according to claim 2,
Means for controlling a driving device provided in the moving body so as to have a speed corresponding to the detected position of the moving body based on the detected position of the moving body and the position speed data; Furthermore, the mobile body control apparatus characterized by the above-mentioned. In a mobile body control device that controls a mobile body comprising an electrical energy generation device and an electrical energy storage device,
Means for detecting the position of the moving body;
Means for detecting an electrical energy storage amount of the electrical energy storage device;
Based on the travel line of the mobile body, the travel schedule of the mobile body, the detected position of the mobile body, and the accumulated amount of electrical energy, the total amount of electrical energy generated by the electrical energy generation device includes a minimum value. Determining means for determining an electric energy generation amount of the electric energy generation device and a discharge amount of the electric energy storage device so that the movable body satisfies the travel schedule while being in an allowable generation range;
Means for requesting the electric energy generating device to generate electric energy according to a determination result by the determining means;
A moving body control device comprising: means for requesting the electric energy storage device to discharge electric energy according to a determination result by the determining means. The mobile control device according to claim 4, wherein
The determination means includes the travel line, the travel schedule, the detected position of the moving body, the electrical energy storage amount, the electrical energy generation characteristics of the electrical energy generation device, and the electrical energy storage characteristics of the electrical energy storage device. Based on the above, the moving body control device determines an electric energy generation amount of the electric energy generation device and a discharge amount of the electric energy storage device. In the moving body control device according to claim 4 or 5,
The moving body control device further comprising means for controlling a driving device provided in the moving body according to a speed target of the moving body that satisfies the travel schedule. In the moving body control device according to claim 4 or 5,
In order to implement | achieve the driving | running | working of the said mobile body which satisfy | fills the said travel schedule, the moving body control apparatus further equipped with the means to adjust the electric current amount supplied to the drive device with which the said mobile body is equipped. The moving body control device according to any one of claims 4 to 7,
The determining means uses the electrical energy storage device to store the electrical energy generated by the electrical energy generation device when the electrical energy generation amount of the electrical energy generation device is less than the amount of electrical energy required to travel the moving body. And then determining that the electric energy generated by the electric energy generation device and the electric energy stored in the electric energy storage device are used for the traveling of the moving object. Control device. The mobile body control device according to any one of claims 1 to 8,
A moving body control device further comprising means for providing the electric energy stored in the electric energy storage device to the outside during a time zone when the moving body does not travel. The mobile body control device according to any one of claims 1 to 9,
A moving body control device further comprising means for storing electric energy received from outside in the electric energy storage device. The moving body control device according to any one of claims 1 to 10,
And a storage control means for generating electrical energy by the electrical energy generator and storing the electrical energy generated by the electrical energy generator in the electrical energy storage device when a charge command is received. A mobile control device. The mobile control device according to claim 11, wherein
The accumulation control means receives the charge command from the switch when a switch provided in the movable body is in an ON state. The moving body control device according to claim 11 or 12,
The mobile control apparatus according to claim 1, wherein the storage control unit receives the charging command from a centralized management system. The moving body control device according to any one of claims 1 to 13,
The mobile body characterized in that the electrical energy generation amount of the electrical energy generation device and the discharge amount of the electrical energy storage device are determined so that the storage amount of the electrical energy storage device falls within a predetermined allowable storage range. Control device.

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