JP4476918B2 - Battery-powered railway train - Google Patents

Description

The present invention relates to a train having an inverter-driven vehicle for railroads, and more particularly to a battery-driven railroad train in which power for the inverter is supplied from a battery.

As an example of the prior art, Japanese Patent Application Laid-Open No. 6-98409 discloses an example of a system for supplying DC power of an inverter from a battery in an inverter-controlled railway electric vehicle. The publication describes that there is an operation mode in which an AC motor is driven via an inverter control device from power supply from an overhead line, and an operation mode in which power is supplied to the same inverter from a battery having a lower voltage than the overhead line mounted on the vehicle. Has been.

JP-A-6-98409

In the battery operation mode described in FIGS. 1 and 2, since the battery is mounted on the same vehicle equipped with the inverter, the battery capacity cannot be increased. Therefore, the vehicle is moved in a non-electrified section without an overhead line. The battery is temporarily used in a special operation mode. Further, FIG. 3 of the same publication proposes a method of pulling a dedicated vehicle equipped with a large-capacity battery with an inverter-driven vehicle for traveling in a long non-electrified section.
The above prior art discloses a concept in terms of battery power supply in an inverter-controlled railway vehicle. However, there is no disclosure or suggestion of what form to take regarding train formation in which a plurality of inverter-controlled vehicles connected by battery power supply are connected. That is, the prior art invention is based on the electric locomotive in view of the description.
In addition to the above publication, JP-A-20
No. 00-83302. However, this publication does not disclose or suggest what form the train formation is made by connecting a plurality of inverter-controlled vehicles by battery power feeding.
It is an object of the present invention to balance a train set, improve redundancy attributed to operation, to reduce the capacity of a battery in a train train connected with a battery-driven inverter-controlled vehicle as a train, and to de-energize all lines It is to provide the most suitable train for traveling on the route of the section.

In order to solve the above problems, an AC motor for driving the vehicle, and a plurality of motor vehicle equipped with an inverter for variable speed drives Re their, in a train of the motor and the inverter are linked a plurality of trailer vehicles not mounted A battery is distributed and mounted on two or more trailer vehicles, the battery terminals are connected in parallel with a common power line across the trailer vehicles, and power is supplied from the power line to the inverter of each motor vehicle. It has a capacitor connected between the DC terminals of the car inverter, and the voltage characteristics of the battery mounted on each trailer vehicle shall have a voltage lower than the capacitor DC voltage during operation of the inverter. It includes a boosting means for boosting a capacitor voltage to a higher voltage than the battery voltage to charge the capacitor by boosting a battery voltage . In addition, step-down means for stepping down the excessive power of the capacitor and regenerating it to the battery is provided.

ADVANTAGE OF THE INVENTION According to this invention, the improvement of the redundancy attributed to driving | operation, the reduction | decrease in battery capacity can be achieved in the battery drive train.
In addition, the environment-friendly pollution can be achieved by adapting the battery-powered train of the present invention to a train running on a non-electrified route.

Hereinafter, the best mode for carrying out the present invention will be described as an embodiment of the present invention with reference to FIGS.

FIG. 1 shows the form of a passenger train set according to the first embodiment of the present invention.
The formation of the vehicle shown in the figure has m cars of the motor vehicle M and n cars of the trailer car, and the trailer cars are connected to the head and the tail of the n cars. M (1) -M (
The motor vehicle m) includes an AC motor 1 for driving the vehicle, an inverter 2 for driving the motor, a control device 3 for controlling the inverter, and a step-up / step-down chopper device 4 for increasing / decreasing the voltage on the DC side of the inverter. Is installed. The trailer vehicles T (1) to T (n) are equipped with a battery 5 such as a lithium battery having a high storage density for supplying DC power to the inverter 2 of the motor vehicle M, and the battery mounted on each trailer vehicle. 5 is connected in parallel by common positive and negative power lines 6 and 7, and electric power is supplied from the power line to the inverter of each motor vehicle via the step-up / step-down chopper device 4.
It should be noted that each of the motor vehicle and trailer vehicle has power lines 6, 7 with other vehicles to be connected.
Connecting device Bb is provided.
In addition, trailer vehicles are provided at the head and tail of the train, and the vehicle has an operation command base 8 that generates a power running / brake command that is a train operation command. The control device 3 and the step-up / step-down chopper device 4 are connected by an on-vehicle LAN 9.
Here, since the inverter 2 that drives the AC motor 1 and its control device 3 are well-known techniques among those skilled in the art, a detailed description thereof will be omitted.

FIG. 2 shows a configuration diagram of the step-up / step-down chopper device 4 in the present embodiment.
In the present embodiment, the rated voltage of the battery 5 is lower (for example, 200 V) than the rated DC voltage (for example, 1500 V) of the inverter 2 because the volume that can be mounted on the vehicle as a battery is limited. Therefore, it is necessary to step down the inverter voltage to the battery voltage in order to boost the battery voltage to the rated voltage of the inverter during power running of the train and to recover the regenerative energy generated in the AC motor from the inverter to the battery during braking.

In FIG. 2, reference numeral 41 denotes a step-up / step-down chopper circuit which is connected between a capacitor provided between the battery 5 and the DC side terminal of the inverter 2. This capacitor 1
0 is provided adjacent to each inverter in order to absorb the harmonic of the direct current due to switching of the inverter. The step-up and step-down chopper circuit 41 is described in FIG. 4 of Japanese Patent Laid-Open No. 6-225458, and the component (41
1 to 415) and the description of the connection relationship is omitted.

In the present embodiment, the voltage detection value Vd of the capacitor 10 and the preset set value Vd
* Is compared with the comparator 42, and the resulting signal Sd and the power running / brake command Su (P, B) from the operation command base are input to the controller 43, and the output of the controller 43 is the output of the chopper circuit 41. It is input to a gate drive circuit 44 that operates the element.

As a result, when the voltage detection value of the capacitor is equal to or lower than the set value or when the power running command Su (P) is received from the train operation command stand, the element 411 of the chopper circuit 41 is turned on / off. The pressure is increased to the set value. On the other hand, when the voltage detection value of the capacitor is equal to or higher than the set value or when the brake command Su (B) is received from the operation command base, the element 413 of the chopper circuit 41 is turned on / off, and thus generated in the brake AC motor. Regenerative energy is recovered from the inverter to the battery.

As described above, according to the present embodiment, the following effects can be obtained.
(1) As a train formation of a train, by distributing and mounting batteries on a plurality of trailer vehicles, when viewed as a train formation, balancing the weight of each vehicle, and especially the movement of the center of gravity of each vehicle during curve traveling Since equalization can be achieved, stabilization during train travel can be achieved.
(2) When a train with a plurality of motor cars connected is run, the rear part has better adhesive properties than the front part in the running direction. As a result, the torque of the rear motor vehicle is greater. Therefore, as the motor vehicle goes to the rear, the power consumption of the battery increases. Nevertheless, if the battery is associated with each inverter of each motor vehicle, the battery voltage of the rear motor vehicle will drop quickly,
For this purpose, it is necessary to increase the battery capacity. On the other hand, in this embodiment, the power supply side averages the power consumption of each motor vehicle that differs depending on the traveling direction by connecting the batteries dispersedly mounted on the formation vehicle in parallel by a common power line. However, the battery capacity can be reduced when viewed as a whole train.

(3) Even if the battery is distributed and mounted on each trailer vehicle and each battery is connected in parallel with a common power line, even if the battery is abnormally reduced in life or the like, the remaining normal battery In addition, it is possible to supply electric power to all motor vehicles of the train, and the redundancy is improved.
(4) By mounting the step-up / step-down chopper device 4 on the motor vehicle, the voltage of the power lines 6 and 7 across the motor vehicle and the trailer vehicle becomes the battery voltage, so that the electric insulation of the power line can be lowered.

Although not shown and described, the battery needs to be replaced because it has a lifetime. For this purpose, means for cutting off the electrical connection between the batteries is provided, and means for detecting the voltage drooping degree over each battery and storing the secular change of the lifetime as a history is provided.

Further, in the battery-driven train shown in the present embodiment, power is regenerated to the battery, but the battery hangs down every time it travels because the amount of work by power running is larger. For this purpose, the battery may be exchanged in a cartridge type, and the power line 6, so that each battery of the train can be collectively charged from the charging facility outside the train.
You may make it provide the drawer part from 7 in a vehicle.

FIG. 3 shows a form of a battery-powered train according to the second embodiment of the present invention.
In this embodiment, the difference from the embodiment of FIG. 1 is that the motor vehicle M is also equipped with an auxiliary battery 5M having a smaller capacity than the battery mounted on the trailer vehicle, and the battery 5M
The positive and negative output terminals are connected to the power lines 6 and 7, respectively.
By mounting this auxiliary battery 5M on the motor vehicle, although it is a short time,
Since electric power can be supplied from the auxiliary battery to the inverter, the effect of enabling reorganization of the vehicle by the motor vehicle alone is obtained.

By the way, in embodiment shown in FIG.1 and FIG.3, although the trailer vehicle is arrange | positioned to the front and rear of train organization, it is not this limitation, Even if motor vehicles are arranged to the front and rear of train organization, It goes without saying that the same effect as described above can be achieved.

Next, the train battery charging method in FIGS. 1 and 3 will be described.

FIG. 4 shows a trailer vehicle equipped with a device that receives power from a power supply facility outside the train and charges a battery mounted on the motor vehicle. The detailed configuration of the mounted charging apparatus 10 will be described with reference to FIGS.
The charging device 10 is connected to the power lines 6 and 7 connected to the battery 5 mounted on the motor vehicle.
DC terminals are connected. Receiving power to the charging device 10 is obtained from the outside of the train via the pantograph 11 mounted on the vehicle with respect to the overhead line 13 connected to a DC or AC power source. However, in the battery-powered train of the present invention, power is not always supplied from the overhead line. Therefore, the pantograph 11 is operated by the pantograph 11 on the basis of a command from the operation command table 8 only during charging, and the pantograph is connected to the overhead line. Is in electrical contact.

FIG. 5 shows a configuration of a charging device that receives power from a DC overhead line. The main circuit 101 constituting the charging device 10 has a circuit configuration similar to that of the step-up / down chopper 41 described above,
In addition to the function of charging the battery from the DC overhead line 13, it has the function of regenerating excess power to the battery in the overhead line during regeneration.
At the time of charging, the charging controller 102 controls the step-down chopper element 1011 in response to the charging command signal Sc and the battery voltage detection signal Vb from the operation command board 8. On the other hand, at the time of regeneration, if the battery voltage detection signal Vb is received and exceeds a set value, the regeneration controller 103 controls the boost chopper element 1012.

FIG. 6 shows a configuration of a charging device that receives power from an AC overhead wire. The charging device 10 includes
A transformer 105 having a primary winding connected from the AC overhead line 13 via the pantograph 11 and a secondary winding of the transformer are connected to convert AC to DC into the power lines 6 and 7 of the battery. It has a PWM converter 106 that outputs and reversely converts it, and a PWM controller 107 that controls the PWM converter.
During charging, the PWM controller 107 receives the charge command signal Sc from the operation command board 8 and the battery voltage detection signal Vb and controls the PWM converter 107 so that the DC output voltage of the PWM converter becomes a set value. On the other hand, at the time of regeneration, if the battery voltage detection signal Vb is received and exceeds the set value, the PWM controller 107 controls the PWM converter during that period to recover excess power from the inverter to the battery in the AC overhead line.

As described above, according to the present embodiment, by mounting the battery charging device by power feeding from the outside of the train on the trailer vehicle on which the battery is mounted, the dielectric strength of the power line extending between the trailer vehicle and the motor vehicle is the battery voltage. Compatible with low pressure. In addition to charging the battery, excess power regenerated from the inverter to the battery at the time of train braking can be recovered to the external power facility, preventing battery destruction due to overcharging of the battery, and suppressing life reduction. There is an effect that can.

In addition, the basic travel of the train set in the present invention is battery-driven, and the charging device described above is not operated over the entire train travel path, but is characterized by operating the charging device only in a specific travel section described below. Is given.

FIG. 7 is a third embodiment of the present invention, and shows a configuration in which the charging device is operated only on the track of the incoming / outgoing line to the station.
The entry / exit line to the station is provided with an overhead line 13 arranged along the track and ground elements 61 and 62 that can detect from the train that the train has entered the track of the entry / exit line.
Under this environment, the battery-powered train of the present invention is operated as follows.
The battery-driven train keeps the pantograph down until it enters the track of the input line of the station. When the ground element 61 is detected by the position detection device provided on the train side, the pantograph operation device 12 shown in FIG. 3 is activated. The pantograph 11 is raised and brought into contact with the overhead line 13. When the battery-powered train departs from the station and the train detects the ground element 62 of the outgoing track, the pantograph is lowered.
Thereby, the battery of the vehicle is charged from the external power facility by the charging device 10 shown in FIGS. 4 to 6 in the section from when the battery-powered train enters the station to the exit. When entering the train, the train is in a brake mode, and power is regenerated from the inverter to the battery. At this time, the charging device 10 prevents the battery from being overcharged.
Operates as described above to recover excess power to external power equipment.

FIG. 8 shows a fourth embodiment of the present invention. The environmental facilities in the input / output lines in FIG. 7 do not need to be provided in all stations on the route, and as shown in FIG. If there is a difference in height, it is only necessary to install environmental facilities at stations with low elevation.
That is, in the case of traveling from the low station A to the high station E, the power running mode continues, so it is necessary to charge in accordance with the battery consumption. However, when traveling in the opposite direction, since the regeneration mode increases, a charging facility environment at a high station E becomes unnecessary.
As described above, the battery-driven train according to the present embodiment extends the driving distance by the battery by loading the step-up / step-down chopper device 4 shown in FIG. 2 and the charging device 10 shown in FIGS. 4 to 6 on the vehicle. it can. Therefore, since the battery-powered train of the present invention can be run instead of the diesel train that is currently running on a non-electric line, environmental pollution can be eliminated.
In addition, in the station A shown in FIG. 8, when providing battery exchange equipment instead of providing electric power feeding equipment (overhead line etc.) as shown in FIG. 7, the battery to be mounted is a cartridge type, and the vehicle has a battery terminal. And a mechanism that facilitates electrical detachment of the power line.

FIG. 9 is a fifth embodiment of the present invention. In FIG. 1 of the present invention, a railway line having a power supply facility for supplying power to the battery of the train from the outside arranged intermittently along the track. It shows about the case where the train provided with the charging device which charges a battery from an overhead wire to a battery drive train is made to run.
Ground elements 63 and 64 are installed that allow the train to detect power supply facilities that supply power to the battery of the train from the outside arranged intermittently along the track. Means for detecting the position of the ground element in the train, and accompanying this detection, the power feeding facility and the train battery are electrically connected via the charging device, or released (from ground elements 63 to 64). Means are provided.
That is, when running the battery-powered train of the present invention on the electrified route,
In the case where a radio interference area due to radio noise caused by contact between the pantograph and the overhead line is regulated, the train is driven only by the battery without lowering the pantograph and receiving power from the outside.
Thereby, the influence which it has on the environment accompanying train traveling can be reduced.

Although not shown, when the regenerative power from the inverter to the battery is excessively generated due to the brake mode in high-speed operation where there is no overhead wire, the battery may not be able to compensate the regenerative power. As a result, the capacitor voltage rises abnormally. For this purpose, a series body of a resistor and a switching element is connected in parallel with the capacitor or battery, and when the capacitor or battery exceeds a predetermined voltage,
By turning on the switching element, the regenerative power is consumed by the resistor.

INDUSTRIAL APPLICABILITY The present invention makes it possible to balance trains in battery-powered trains, improve redundancy due to operation, reduce battery capacity, and use the battery of the present invention for non-electrified trains. By adapting the driving train, environmental pollution can be eliminated, which is useful for providing a battery-powered railway train.

The block diagram of the battery drive train which shows 1st embodiment of this invention Specific configuration of the step-up / down chopper device in FIG. The block diagram of the battery drive train which shows 2nd embodiment of this invention The block diagram which charges the battery in 1st and 2nd embodiment of this invention Specific configuration diagram of the charging device in FIG. FIG. 4 shows another specific configuration diagram of the charging device. The figure which shows 3rd embodiment of this invention and illustrates the charge form to a train The figure which shows 4th embodiment of this invention and illustrates the charge form to a train The figure which shows 5th embodiment of this invention and illustrates the charge form to a train

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... AC motor, 2 ... Inverter, 3 ... Control device, 4 ... Buck-boost chopper device,
DESCRIPTION OF SYMBOLS 5 ... Battery, 6, 7 ... Power line, 9 ... On-vehicle LAN, T ... Trailer vehicle, M ... Motor vehicle, Bb ... Battery power line connection apparatus.

Claims (2)

In a train train that connects an AC motor that drives a vehicle, a plurality of motor vehicles equipped with an inverter that drives the variable speed motor, and a plurality of trailer vehicles that are not equipped with the motor and the inverter,
A battery is distributed and mounted on two or more of the trailer cars, and terminals of the batteries are connected in parallel by a common power line between the trailer cars, and power is supplied from the power line to the inverters of the plurality of motor cars. ,
A capacitor connected between the DC terminals of the inverter of each motor vehicle, and the voltage characteristics of the battery mounted on each trailer vehicle have a voltage lower than the capacitor DC voltage during operation of the inverter And each motor vehicle is provided with a boosting means for charging the capacitor by boosting the battery voltage to boost the capacitor voltage to a voltage higher than the battery voltage. An AC motor for driving the vehicle, and a plurality of motor vehicle equipped with an inverter for variable speed drives Re their, in a train of the motor and the inverter is connected to a plurality of trailer vehicles not mounted,
A battery is distributedly mounted on two or more of the trailer vehicles, the battery terminals are connected in parallel by a common power line between the trailer vehicles, and power is supplied from the power line to the inverters of the plurality of motor vehicles. ,
A capacitor connected between the DC terminals of the inverter of each motor vehicle, and the voltage characteristic of the battery mounted on each trailer vehicle has a voltage lower than the capacitor DC voltage during operation of the inverter And boosting means for charging the capacitor by boosting the battery voltage to boost the capacitor voltage to a voltage higher than the battery voltage in each motor vehicle, and reducing the excess power of the capacitor to regenerate the battery. A battery-powered railway train comprising a step-down means.

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