JP2012153364A - Railway train carrying-in/out method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To continuously move a railway train between rail tracks of different track gauges.SOLUTION: A railway train carrying-in/out method uses a system for moving a railroad train between the rail tracks of different track gauges which includes: a railway train; a freight train 10 including a train loading part 12 for loading the railway train and traveling on a specific rail track; a freight train locomotive 10a; a railway train locomotive; and a traverser 20 where a first rail track part having the same track gauge size as that of the predetermined rail track and a second rail track part having the same track gauge size as that of the specific rail track on which the freight train travels are arranged side by side. The traverser makes a state in which the end of the predetermined rail track, the end of the specific rail track and the first rail track part are arrayed on the same line, and in such a state, the railway train is carried in to the train loading part of the freight train while causing the freight train locomotive to standby at the second rail track part of the traverser. The traverser makes a state in which the end of the predetermined rail track, the end of the specific rail track and the second rail track part are arrayed on the same line and, in such a state, the railway train loaded on the train loading part is carried out while causing the railway train locomotive to standby at the first rail track part of the traverser.

Description

  The present invention relates to a railway train loading / unloading method suitable for loading / unloading a railway train on / from a freight train that travels with the railway train mounted thereon.

  Currently, various techniques for continuously moving trains in track sections with different gauge dimensions (hereinafter referred to as “different gauge tracks”) have been proposed and put into practical use. For example, at borders with different-gauge tracks, there is a technology that lifts the body of a freight car with a jack and replaces the carriage mounted below the carriage with a carriage with a different gauge (hereinafter referred to as “cart carriage replacement method”). It has been put into practical use.

  Further, by laying three rails in parallel, a track having a wide gauge (for example, a standard gauge between the gauges of 1435 mm) composed of two outer rails, one outer rail, and one inner rail A technology (hereinafter referred to as “three-wire rail system”) that constitutes a track having a narrow gauge (for example, a narrow gauge of 1067 mm) is in practical use. If this three-wire rail system is adopted, two types of trains with different gauges can be run.

  In recent years, development of a “variable gauge variable vehicle” that changes the gauge distance by moving the left and right wheels in the direction of the axle has been promoted (see, for example, Patent Document 1). When such a variable-gauge vehicle is employed, a jack or the like for exchanging the carriage becomes unnecessary and an additional laying operation of the rail becomes unnecessary.

JP-A-8-332950 (first page, FIG. 1)

  However, if the above-mentioned “cart replacement method” is adopted, ground work such as a jack and a large work space for exchanging the cart are required, and more work and time are required for exchanging the cart. There's a problem. Moreover, when the above-mentioned “three-line rail system” is adopted, when traveling two types of trains with different gauges, one outer rail is commonly used. There is a problem that a rail is worn and damaged earlier than other rails.

  In addition, in a “variable gauge vehicle” as described in Patent Document 1, a mechanism for changing the gauge (gauge changing mechanism) is extremely complicated, so that the durability of the mechanism, the certainty of the gauge changing operation, etc. Therefore, it is difficult to put it into practical use at this stage.

  An object of the present invention is to provide a railway train loading / unloading method that enables loading of a railway train traveling on a predetermined track into a freight train and unloading of a railway train mounted on the freight train.

The invention according to claim 1 is provided with a railroad train composed of a plurality of railcars and traveling on a predetermined track, and a train mounting portion on which the railcar is mounted in a connected state, and is different from the predetermined railroad. A freight train that travels on a specific track having dimensions between gauges, a freight train locomotive that is connected to the freight train and drives the freight train, and a railroad that is connected to a railroad train that travels on a predetermined track and drives the railroad train Using the train locomotives and these trains and locomotives, both the loading of the railroad train into the train mounting portion of the freight train and the unloading of the railroad train mounted on the train mounting portion. Using an inter-gauge track train moving system comprising a traverser to perform, carrying in the rail train to the train mounting portion of the freight train, and unloading the rail train mounted in the train mounting portion. If a railway train loading and unloading method to realize,
The traverser includes a first track portion having the same gauge size as the predetermined track, and a second track portion having the same track size as the specific track on which the freight train travels, and the first track portion; A second track portion is provided in parallel, an end portion of the predetermined track and an end portion of the specific track face each other on the same line, and the traverser is disposed therebetween, and the first track portion is the second track portion. The height from the ground of the first track portion is higher than the track portion, and the height from the ground of the rail of the train mounting portion of the freight train placed on the second track portion. The end of the predetermined track, the end of the specific track, and the first track portion are aligned on the same line, and the end of the predetermined track and the specific track are set by the traverser. The end of the track and the said The two track portions are aligned with each other on the same line, and the rail of the freight train that has entered the specific track, the first track portion of the traverser, and the predetermined track are continuous. One predetermined track is configured to carry in the railroad train to the train mounting portion of the freight train, and to carry out the railroad train mounted in the train mounting portion. The freight train locomotive is set in a standby state on the second track portion of a traverser, and the railroad train locomotive is set in a standby state on the first track portion of the traverser when being carried out. To do.

  According to the first aspect of the present invention, the first track portion of the traverser and the train transport section of the freight train are connected, the railway train locomotive is connected to the railway train, and the driving force of the railway train locomotive is used. By running the railroad train, the railroad train can be carried into the train mounting portion of the freight train via the first track portion of the traverser. Therefore, railway trains can be easily and quickly mounted on freight trains without using jacks, etc., so that the travel time of railroad trains can be greatly reduced on inter-track tracks that change from a specified track to a specific track. Can do.

  According to the invention described in claim 1, the freight train locomotive is connected in front of the traveling direction of the freight train on which the railway train is mounted, and the freight train is driven by the driving force (traction force) of the freight train locomotive. The locomotive for freight trains can be made to travel on the second track portion of the traverser. Then, the connected state between the freight train locomotive and the freight train is released, the traverser is moved to connect the first track portion of the traverser and the train transport section of the freight train, and the rail train locomotive is connected to the train transport section. The railway train can be carried out via the first track portion of the traverser by being connected to the railway train and running the railway train with the driving force of the locomotive for the railway train. Therefore, it is possible to easily and quickly carry out the railway train from the freight train without using a jack, etc., so that the travel time of the railway train can be greatly shortened in the inter-track between the specific track and the predetermined track. Can do.

Further, since the freight train can be mounted on the train mounting portion while the railway train traveling on the predetermined track is connected, the specific train can be traveled with the railroad train mounted. Therefore, the railroad train can be continuously moved on the different-track track provided with both the predetermined track and the specific track.
Moreover, it is not necessary to use the conventional “carriage replacement method” when placing a railroad train that was traveling on a specific track on a specific track. A work space is not required, and time and labor required for exchanging the carriage can be reduced. For this reason, the travel time of the railway train can be greatly shortened. In addition, since it is not necessary to adopt the conventional “three-wire rail system”, it is possible to prevent wear and damage of the rail without applying an excessive load to one rail. Moreover, since a complicated gauge conversion mechanism is not used, the railway train can be moved safely and reliably.

  According to the present invention, a railway train can be continuously moved on a different-track track without requiring a complicated mechanism or a large ground facility, and the moving time can be remarkably shortened.

It is explanatory drawing for demonstrating the outline | summary of the different rail track train moving system which concerns on 1st Embodiment. It is sectional drawing which shows the state which mounted the Shinkansen freight train used on the different gauge track train moving system shown in FIG. 1 on a standard gauge. It is a partially cutaway side view of the Shinkansen freight train shown in FIG. FIG. 2 is a cross-sectional view of a traverser used in the different-gauge track train moving system shown in FIG. 1. It is explanatory drawing for demonstrating the process of carrying in a conventional line wagon into a Shinkansen freight car using the traverser shown in FIG. It is explanatory drawing for demonstrating the process of carrying out a conventional line freight car from a Shinkansen freight car using the traverser shown in FIG. Same as above It is explanatory drawing for demonstrating the process of carrying in a conventional line freight car into a Shinkansen freight car using the traverser which also serves as a branching device in the different-gauge track train moving system which concerns on 2nd Embodiment. It is explanatory drawing for demonstrating the process of carrying out a conventional line freight car from a Shinkansen freight car using the traverser which also serves as a turnout in the different-gauge track train moving system which concerns on 2nd Embodiment. Same as above It is explanatory drawing for demonstrating the process of carrying in a conventional line freight car into a Shinkansen freight car using the train carrying-in / out vehicle in the different-gauge track train moving system which concerns on a reference example. It is explanatory drawing for demonstrating the process of carrying out a conventional line freight car from a Shinkansen freight car using the train carrying-in / carrying-out vehicle in the different-gauge track train moving system which concerns on a reference example.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the present embodiment, the train is continuously moved on a track section (trajectory between different gauges) composed of a narrow gauge (track with a gauge distance of 1067 mm) and a standard gauge (track with a gauge distance of 1435 mm). The “railway train moving system” will be described.

[First embodiment]
First, the different-track track train moving system according to the first embodiment of the present invention will be described with reference to FIGS. Different gauge track train movement system comprises a Shinkansen freight trains 10 and traverser 20 to be described later, as shown in FIG. 1, a narrow gauge L _N laid Hokkaido side, narrow gauge L _N laid Honshu side And, the “straight-line operation” of the conventional freight train 1 is realized by a different-gauge track composed of the standard gauge L _S in the Seikan tunnel laid between these narrow gauges L _N. The narrow gauge L _N is a predetermined path in the present invention, and the standard gauge L _S is a specific path in the present invention.

As shown in FIG. 1, the conventional freight train 1 is composed of a plurality of connected conventional line wagons 2 and a conventional line locomotive 3 that drives these conventional line wagons 2. Conventional lines wagons 2 conventional lines freight train 1 is narrow gauge L _N above to be able to travel, narrow gauge L _N a pair of right and left wheels 2a arranged at corresponding intervals to gauge size (1067mm) of (See FIG. 2). The railway train in the present invention is configured by connecting a plurality of conventional railway wagons 2.

The conventional freight car 2 cannot travel on the standard gauge L _S in the Seikan Tunnel, but is mounted inside the Shinkansen freight car 11 of the Shinkansen freight train 10 described later, as shown in FIG. As it is transported at high speed, it will eventually move through the Seikan Tunnel. Therefore, the conventional freight train 1 continues from the predetermined starting point P _S on the Hokkaido side (for example, Hakodate Station) to the predetermined destination point P _G on the Honshu side (for example, Tokyo Station) via the Seikan Tunnel. Can be moved.

  Next, the configuration of the Shinkansen freight train 10 used in the inter-orbit track train moving system according to the present embodiment will be described with reference to FIGS.

As shown in FIGS. 1 and 2, the Shinkansen freight train 10 is composed of a plurality of connected Shinkansen freight cars 11 and a Shinkansen locomotive 10 a that drives these Shinkansen freight cars 11. It travels on _{S at} the same speed as the Shinkansen 100.

Shinkansen wagons 11, as shown in FIGS. 2 and 3, the body 12 functions as the train mounting unit for mounting remain connected state conventional lines wagons 2, the standard gauge L _S below the vehicle body 12 gauge size (1435Mm ) And a pair of left and right wheels 13 arranged at intervals corresponding to the left and right wheels 13, an axle 14 for connecting the left and right wheels 13, and the like. The height of the Shinkansen freight car 11 is substantially the same as the height of the conventional Shinkansen 100 vehicle, as shown in FIG. A freight train in the present invention is configured by connecting a plurality of Shinkansen freight cars 11.

Inside the body 12 of the Shinkansen wagons 11, as shown in FIG. 2, gauge size (10 narrow gauge L _N
Rails 12a arranged at intervals corresponding to 67 mm). The rail 12 a is for guiding the wheel 2 a of the conventional line wagon 2 when the conventional line wagon 2 is carried into the vehicle body 12. As shown in FIG. 3, the rail 12 a is also provided in the connecting portion 15 that connects the Shinkansen freight cars 11, so that the rail 12 a is carried into the vehicle body 12 of the Shinkansen freight car 11 in a state where the conventional railway freight cars 2 are connected. Can do.

  Next, the configuration of the traverser 20 used in the different rail track train moving system according to the present embodiment will be described with reference to FIGS.

  As shown in FIGS. 5 to 7, the traverser 20 is a structure having a rectangular planar shape, and a direction perpendicular to the traveling direction of the railway vehicle in a state where a predetermined railway vehicle is placed on the upper portion. To move on. As shown in FIGS. 4 to 7, the traverser 20 in the present embodiment has the conventional locomotive 3 and the Shinkansen locomotive 10a placed on the upper part thereof, and the direction of the arrow A and the arrow B by the drive device 20a. Configured to move in the direction.

The traverser 20 is installed in the _two trajectory conversion units P ₁ and P _{2 shown} in FIG. By using the traverser 20, the traveling state of the conventional railway wagon 2 on the narrow gauge L _N can be converted into a transported condition on the standard gauge L _S (a state of being carried on the Shinkansen railway carriage 11), It is possible to convert the transported state on the standard rail L _S of the incoming freight car 2 into a traveling state on the narrow rail L _N.

  As shown in FIGS. 4 to 7, the traverser 20 includes a narrow-gauge portion 21 that travels the conventional railway freight train 2 and the conventional railway locomotive 3 of the conventional freight train 1, and the Shinkansen freight train 11 of the Shinkansen freight train 10. And a standard gauge portion 22 for running the Shinkansen locomotive 10a is provided in parallel. The narrow gauge portion 21 is the first track portion in the present invention, and the standard track portion 22 is the second track portion in the present invention.

The narrow gauge portion 21 of the traverser 20 is provided at a position higher than the standard gauge portion 22. As shown in FIG. 4, the height H ₁ of the narrow gauge portion 21 of the traverser 20 from the ground is the rail 12a of the Shinkansen freight car 11 placed on the standard gauge portion 22 (or the standard gauge L _S ) of the traverser 20. Is set to be equal to the height H ₂ from the ground. Therefore, by moving the traverser 20 in the direction of arrow A or arrow B and aligning the narrow gauge portion 21 of the traverser 20 with the rail 12a of the Shinkansen freight car 11, a continuous narrow gauge can be configured. it can.

  Subsequently, using FIGS. 5 to 7, a method of bringing the conventional train wagon 2 into the Shinkansen freight car 11 (train delivery method) and a method of carrying out the conventional train wagon 2 from the Shinkansen freight car 11 (train delivery method). ).

<Train delivery method>
First, a method of carrying the conventional freight car 2 of the conventional freight train 1 into the Shinkansen freight car 11 of the Shinkansen freight train 10 will be described with reference to FIG. In the following description, the conventional freight train 2 of the conventional freight train 1 that has traveled from Hokkaido to Honshu using the traverser 20 installed in the trajectory conversion section P ₁ on the Hokkaido side is used for the Shinkansen freight. Let us exemplify a method of bringing the train 10 into the Shinkansen freight car 11.

First, the traverser 20 installed in the trajectory conversion part P ₁ on the Hokkaido side is moved, and the narrow gauge portion 21 of the traverser 20 and the narrow gauge L _N on the Hokkaido side are aligned to form a continuous narrow gauge. To do. In this embodiment, as shown in FIGS. 5 (a) and 5 (b), by moving the traverser 20 in the direction of arrow B (the lower side of the drawing in FIG. 5), the narrow gauge portion 21 of the traverser 20 and the Hokkaido side The narrow gauge L _N is aligned to form a continuous narrow gauge. In addition, the Shinkansen locomotive 10a is placed on the standard rail portion 22 of the traverser 20 as shown in FIG.

Next, as shown in FIG. 5A, the end of the Shinkansen freight train 10 of the Shinkansen freight train 11 on the Hokkaido side (the right end of the drawing in FIG. 5) is the Honshu side (the left side of the drawing in FIG. 5). By bringing them close, the rail 12a (not shown) of the Shinkansen freight car 11 and the narrow gauge portion 21 of the traverser 20 are connected. Thus, a continuous narrow gauge composed of the narrow gauge L _N on the Hokkaido side, the narrow gauge portion 21 of the traverser 20 and the rail 12a of the Shinkansen freight car 11 is formed. In addition, a Shinkansen locomotive 10a for traction (not shown) is connected to the end of Honshu side of the Shinkansen freight car 11 shown in FIG.

Next, the conventional line freight train 1 that has traveled on the narrow gauge L _N on the Hokkaido side is entered into the trajectory conversion section P ₁ on the Hokkaido side. At this time, the conventional line locomotive 3 is positioned on the Hokkaido side by reversing the traveling direction of the conventional line freight train 1, and the conventional line locomotive 3 is pushed to the Honshu side to run. To. Then, as shown in FIGS. 5 (a) and 5 (b), the conventional line wagon 2 is sequentially placed on the narrow gauge portion 21 of the traverser 20 and the rail 12 a of the Shinkansen freight car 11, and the conventional line wagon 2 is moved to the Shinkansen freight car 11. Into the vehicle body 12.

Next, after the conventional line wagon 2 is completely carried into the vehicle body 12 of the Shinkansen freight car 11, the conventional line locomotive 3 is separated from the conventional line wagon 2 as shown in FIG. By reversing the traveling direction of the vehicle 3, the conventional locomotive 3 is returned to the narrow gauge L _N on the Hokkaido side via the narrow gauge portion 21 of the traverser 20.

  Thereafter, as shown in FIG. 5D, by moving the traverser 20 in the direction of arrow A, the Shinkansen freight car 11 and the Shinkansen locomotive 10a placed on the standard gauge portion 22 of the traverser 20 In alignment, the Shinkansen locomotive 10a is connected to the end of the Shinkansen freight car 11 on the Hokkaido side. Then, as shown in FIG. 5 (e), the Shinkansen freight train 10 in which the conventional freight car 2 is mounted on the Shinkansen freight car 11 is caused to travel toward Honshu.

In addition, when the conventional railway freight train 2 of the conventional railway freight train 1 that has traveled from Honshu to Hokkaido is carried into the Shinkansen freight railway 11 of the Shinkansen freight train 10 at the trajectory conversion section P ₂ on the Honshu side. A method similar to the above method can be employed.

<Train unloading method>
Next, a method for carrying out the conventional freight car 2 of the conventional freight train 1 from the Shinkansen freight car 11 of the Shinkansen freight train 10 will be described with reference to FIG. In the following description, from the Shinkansen freight train 11 of the Shinkansen freight train 10 that has traveled from Honshu to Hokkaido via the Seikan Tunnel, using the traverser 20 installed in the trajectory conversion section P ₁ on the Hokkaido side, Let us exemplify a method of carrying out the conventional line freight car 2 of the conventional line freight train 1.

First, the traverser 20 installed in the trajectory conversion section P ₁ on the Hokkaido side is moved, and the standard gauge portion 22 of the traverser 20 and the standard gauge L _S in the Seikan tunnel are aligned, so that the continuous one Configure the standard gauge. In the present embodiment, as shown in FIG. 6 (a), the traverser 20 is moved in the direction of arrow A (upper side of the drawing in FIG. 6), so that the standard gauge portion 22 of the traverser 20 and the Seikan tunnel (shown in the figure). The standard gauge L _S is not aligned, and a continuous standard gauge is formed.

Next, the Shinkansen freight train 10 that has traveled on the standard gauge L _S in the Seikan Tunnel is entered into the Hokkaido-side track conversion section P ₁ set as described above. Then, as shown in FIG. 6 (a), the Shinkansen locomotive 10a is put on the standard gauge portion 22 of the traverser 20, and then the Shinkansen freight car 11 is separated from the Shinkansen locomotive 10a.

Next, as shown in FIG. 6B, by moving the traverser 20 in the direction of arrow B, the rail 12a (not shown) of the Shinkansen freight car 11, the narrow gauge portion 21 of the traverser 20, and the narrow gauge on the Hokkaido side. By aligning with L _N , a continuous narrow gauge is formed. Then, as shown in FIG. 6B, the conventional locomotive 3 placed on the narrow gauge L _N on the Hokkaido side is caused to enter the narrow gauge portion 21 of the traverser 20.

  Next, as shown in FIG. 6 (c), the conventional line locomotive 3 is connected to the Hokkaido side end of the conventional line wagon 2 mounted inside the Shinkansen freight car 11. Then, as shown in FIG. 6 (d), the conventional line wagon 2 is unloaded from the Shinkansen freight car 11 by pulling the conventional line wagon 2 to the Hokkaido side by the driving force of the conventional line locomotive 3. Thereafter, the conventional freight train 1 is driven toward Hokkaido.

In addition, as shown to Fig.7 (a), the conventional line locomotive 3 can also be mounted in the narrow gauge part 21 of the traverser 20 previously. When the conventional locomotive 3 is placed in advance on the narrow gauge portion 21 of the traverser 20 in this way, the steps shown in FIG. 6B (the narrow gauge portion 21 of the traverser 20 and the narrow gauge L on the Hokkaido side). After aligning _N , the step of causing the conventional locomotive 3 placed on the narrow gauge L _N on the Hokkaido side to enter the narrow gauge portion 21 of the traverser 20 can be omitted.

In addition, from the Shinkansen freight train 11 of the Shinkansen freight train 10 that has traveled from Hokkaido to Honshu via the Seikan tunnel, the conventional freight train 2 of the conventional freight train 1 is transferred from the trajectory conversion section P ₂ on the Honshu side. When carrying out, the same method as the above method can be adopted.

In the different-gauge track train moving system in the embodiment described above, the conventional railway wagon 2 traveling on the narrow gauge L _N can be mounted in the connected state in the vehicle body 12 of the Shinkansen railway 11 of the Shinkansen freight train 10. it can. The Shinkansen freight trains 10, can travel standard gauge L _S in a state equipped with conventional lines wagons 2 (see FIGS. 1 to 3). Therefore, the conventional railway wagon 2 can be continuously moved in the different-gauge track provided with both the narrow gauge L _N and the standard gauge L _S.

Moreover, when moving the conventional lines wagons 2 on narrow gauge L _N on standard gauge L _S (or when moving the standard gauge L conventional lines wagons 2 _S on narrow-gauge L _N), a conventional "truck Since it is not necessary to adopt the “repeat system”, ground work such as a jack and a large work space for exchanging the cart are not required, and the time and labor required for exchanging the cart can be reduced. For this reason, the movement time of the conventional railway freight car 2 can be significantly shortened. In addition, since it is not necessary to adopt the conventional “three-wire rail system”, it is possible to prevent wear and damage of the rail without applying an excessive load to one rail. Moreover, since the complicated gauge conversion mechanism is not used, the conventional railway wagon 2 can be moved safely and reliably.

  Moreover, in the different-gauge track train moving system in embodiment described above, since the rail 12a which guides the wheel 2a of the conventional railway freight car 2 is provided inside the car body 12 of the Shinkansen freight car 11 of the Shinkansen freight train 10. The conventional railway wagon 2 can be easily mounted in the connected state (see FIG. 3).

Further, in the different-gauge track train moving system in the embodiment described above, the narrow-gauge portion 21 of the traverser 20 and the rail 12a provided in the vehicle body 12 of the Shinkansen freight car 11 are connected to each other, and the conventional locomotive is connected. 3 is connected to the conventional railway wagon 2 and the conventional railway wagon 2 is driven by the driving force of the conventional railway locomotive 3, so that the conventional railway freight car 2 passes through the narrow gauge portion 21 of the traverser 20 and becomes a bullet train. 11 (see FIG. 5). Accordingly, it is possible to easily and quickly installed conventional lines wagons 2 inside the Shinkansen wagons 11 without using a jack or the like, in different gauge track transitions from the narrow gauge L _N to the standard gauge L _S, native The travel time of the railway wagon 2 can be greatly shortened.

Further, in the different-gauge track train moving system in the embodiment described above, the Shinkansen locomotive 11 is caused to travel by the driving force (traction force) of the Shinkansen locomotive 10a, and the Shinkansen locomotive 10a enters the standard gauge portion 22 of the traverser 20. Can be made. Then, the Shinkansen locomotive 10a is disconnected from the Shinkansen freight car 11, and the traverser 20 is moved to connect the narrow gauge portion 21 of the traverser and the rail 12a provided in the vehicle body 12 of the Shinkansen freight car 11. The conventional line wagon 2 is connected to the conventional line wagon 2 inside the Shinkansen freight car 11 and is driven by the driving force of the conventional line locomotive 3 so that the conventional line wagon 2 passes through the narrow gauge portion 21 of the traverser 20. And can be carried out (see FIGS. 6 and 7). Therefore, since the conventional railway wagon 2 can be easily and quickly carried out from the Shinkansen railway freight car 11 without using a jack or the like, the conventional railway wagon can be moved in a different-gauge trajectory that shifts from the standard gauge L _S to the narrow gauge L _N. 2 travel time can be greatly shortened.

[Second Embodiment]
Next, with reference to FIG. 8 to FIG. 10, a different rail track train moving system according to the second embodiment of the present invention will be described. The different-gauge track train moving system according to the present embodiment is obtained by changing the configuration of the traverser used in the first embodiment, and the other configurations are substantially the same as those of the first embodiment. It is. Accordingly, the same components as those in the first embodiment will be described with the same reference numerals as those in the first embodiment.

  As shown in FIGS. 8 to 10, the traverser 30 used in the different-gauge track train moving system according to the present embodiment includes the conventional line train 2 and the conventional line locomotive 3 of the conventional line train 1. A narrow gauge portion 31 for running the vehicle and a standard gauge portion 32 for running the Shinkansen freight car 11 and the Shinkansen locomotive 10a of the Shinkansen freight train 10 are provided in parallel. The narrow gauge portion 31 is the first track portion in the present invention, and the standard track portion 32 is the second track portion in the present invention.

  A surface (hereinafter, referred to as “standard rail surface”) 32a provided with a standard rail portion 32 of the traverser 30 is fixed to the ground. Further, a surface (hereinafter referred to as “narrow gauge surface”) 31a on which the narrow gauge portion 31 of the traverser 30 is provided is configured to move in the arrow A direction and the arrow B direction, as shown in FIGS. Yes. And the narrow gauge surface 31a is arrange | positioned in the position higher than the standard gauge surface 32a, and if the narrow gauge surface 31a moves to the arrow B direction, as shown in FIG.8 (c), (d), the standard gauge surface 32a will be shown. It is located below the narrow gauge surface 31a.

The height of the narrow gauge portion 31 of the traverser 30 from the ground is the same as the height of the rail 12a of the Shinkansen freight car 11 mounted on the standard gauge portion 32 (or the standard gauge L _S ) of the traverser 30 from the ground. Is set. For this reason, one continuous narrow gauge can be comprised by aligning the narrow gauge part 31 of the traverser 30 and the rail 12a of the Shinkansen freight car 11.

Moreover, the narrow gauge part 31 of the traverser 30 is provided in the state bent so that one edge part side might be spaced apart from the standard gauge part 32, as shown in FIGS. For this reason, as shown in FIG. 8D, when the narrow gauge surface 31a of the traverser 30 is positioned above the standard gauge surface 32a, the narrow gauge portion 31 of the traverser 30 is branched from the extending direction of the standard gauge portion 32. be able to. For this reason, the traverser 30 functions as a branching device of the standard gauge L _S and the narrow gauge L _N.

  Subsequently, using FIGS. 8 to 10, a method of carrying in the conventional train wagon 2 to the Shinkansen freight car 11 (train delivery method) and a method of carrying out the conventional train wagon 2 from the Shinkansen freight car 11 (train delivery method). ).

<Train delivery method>
First, a method for carrying the conventional freight train 2 of the conventional freight train 1 into the Shinkansen freight train 11 of the Shinkansen freight train 10 will be described with reference to FIG. In the following description, the conventional freight train 2 of the conventional freight train 1 that has traveled from Hokkaido to Honshu using the traverser 30 installed in the trajectory conversion section P ₁ on the Hokkaido side is used for the Shinkansen freight. Let us exemplify a method of carrying in the Shinkansen freight car 11 of the train 10.

First, as shown in FIG. 8 (a), the narrow gauge surface 31a of the installed traverser 30 in orbital transfer portion P ₁ of the Hokkaido side is moved in the direction of arrow A to expose the standard gauge surface 32a of the traverser 30. In this way to expose the standard gauge surface 32a of the traverser 30, and the standard gauge L _S of Seikan in the tunnel, a standard gauge portion 32 of the traverser 30, and the standard gauge L _S provided partially Hokkaido side, by One continuous standard gauge is constructed.

  Next, the Shinkansen freight train 10 is entered from the Hokkaido side, as shown in FIG. 8 (a), into one continuous standard gauge constructed as described above. Then, after the Shinkansen freight train 11 of the Shinkansen freight train 10 is brought close to the Honshu side (left side in FIG. 8) end of the traverser 30, the Shinkansen locomotive 10a is separated from the Shinkansen freight car 11, and as shown in FIG. 8 (b). Reverse the direction of travel of the Shinkansen locomotive 10a and return it to the Hokkaido side.

Next, as shown in FIGS. 8B and 8C, the narrow gauge surface 31 a of the traverser 30 is moved in the direction of arrow B, and the narrow gauge L _N on the Hokkaido side, the narrow gauge portion 31 of the traverser 30, and the Shinkansen freight car 11 By aligning the rails 12a (not shown), a continuous narrow gauge (curved track) is formed.

Next, the conventional line freight train 1 is made to enter the continuous narrow gauge configured as described above from the narrow gauge L _N on the Hokkaido side. At this time, the conventional line locomotive 3 is positioned on the Hokkaido side by reversing the traveling direction of the conventional line freight train 1, and the conventional line locomotive 3 is pushed to the Honshu side to run. To. Then, as shown in FIGS. 8 (c) and 8 (d), the conventional line wagon 2 is sequentially placed on the narrow gauge portion 31 of the traverser 30 and the rail 12 a of the Shinkansen freight car 11, and the conventional line wagon 2 is moved to the Shinkansen freight car 11. Into the vehicle body 12.

After the conventional train wagon 2 is completely carried into the vehicle body 12 of the Shinkansen train 11, the conventional train locomotive 3 is separated from the conventional train locomotive 3 as shown in FIG. Is reversed, the conventional locomotive 3 is returned to the narrow gauge L _N on the Hokkaido side via the narrow gauge section 31 of the traverser 30. And as shown in FIG.8 (e), the standard gauge surface 32a of the traverser 30 is exposed by moving the narrow gauge surface 31a of the traverser 30 to the arrow A direction. Thereafter, a bullet train locomotive 10a which has been placed on the standard gauge L _S Hokkaido side is entering the traverser 30, connecting the Shinkansen locomotive 10a Hokkaido end Shinkansen wagons 11, FIG. 8 (f) As shown in FIG. 2, the Shinkansen freight train 10 in a state where the conventional train wagon 2 is mounted on the Shinkansen train 11 is caused to travel toward Honshu.

In addition, when the conventional railway freight train 2 of the conventional railway freight train 1 that has traveled from Honshu to Hokkaido is carried into the Shinkansen freight railway 11 of the Shinkansen freight train 10 at the trajectory conversion section P ₂ on the Honshu side. A method similar to the above method can be employed.

<Train unloading method>
Next, a method for carrying out the conventional railway wagon 2 of the conventional railway freight train 1 from the Shinkansen railway freight car 11 of the Shinkansen railway freight train 10 will be described with reference to FIG. In the following description, from the Shinkansen freight train 11 of the Shinkansen freight train 10 that has traveled from Honshu to Hokkaido via the Seikan Tunnel, using the traverser 30 installed in the trajectory conversion section P ₁ on the Hokkaido side, Let us exemplify a method of carrying out the conventional line freight car 2 of the conventional line freight train 1.

First, as shown in FIG. 9 (a), the narrow gauge surface 31a of the installed traverser 30 in orbital transfer portion P ₁ of the Hokkaido side is moved in the direction of arrow A to expose the standard gauge surface 32a of the traverser 30. In this way to expose the standard gauge surface 32a of the traverser 30, and the standard gauge L _S of Seikan in the tunnel, a standard gauge portion 32 of the traverser 30, and the standard gauge L _S provided partially Hokkaido side, by One continuous standard gauge is constructed.

Next, the Shinkansen freight train 10 that has traveled on the standard gauge L _S in the Seikan Tunnel is entered into the Hokkaido-side track conversion section P ₁ set as described above. Then, after the Shinkansen locomotive 10a is put into the standard rail portion 32 of the traverser 30, the Shinkansen freight car 11 is separated from the Shinkansen locomotive 10a as shown in FIG. 9 (b), and the Shinkansen locomotive 10a is partially moved to the Hokkaido side. To the standard gauge L _S provided in

Next, as shown in FIGS. 9B and 9C, the narrow gauge surface 31a of the traverser 30 is moved in the direction of the arrow B, so that the narrow gauge L _N on the Hokkaido side, the narrow gauge portion 31 of the traverser 30, and the bullet train 11 By aligning the rails 12a (not shown), a continuous narrow gauge (curved track) is formed. Then, the conventional line locomotive 3 placed on the narrow gauge L _N on the Hokkaido side is caused to enter the narrow gauge portion 31 of the traverser 30.

  Next, as shown in FIG. 9 (c), the conventional line locomotive 3 is connected to the Hokkaido side end of the conventional line wagon 2 mounted inside the Shinkansen freight car 11. Then, as shown in FIGS. 9 (d) and 9 (e), the conventional line wagon 2 is pulled from the Shinkansen freight car 11 by pulling the conventional line wagon 2 to the Hokkaido side by the driving force of the conventional line locomotive 3. Take it out. Thereafter, the conventional freight train 1 is driven toward Hokkaido.

In addition, as shown to Fig.10 (a), the conventional line locomotive 3 can also be mounted in the narrow gauge part 31 of the traverser 30 previously. If the conventional locomotive 3 is placed in advance on the narrow gauge portion 31 of the traverser 30 in this way, the process as shown in FIG. 9C (the narrow gauge portion 31 of the traverser 30 and the narrow gauge L on the Hokkaido side). After aligning _N , the step of causing the conventional locomotive 3 placed on the narrow gauge L _N on the Hokkaido side to enter the narrow gauge portion 31 of the traverser 30 can be omitted.

In addition, from the Shinkansen freight train 11 of the Shinkansen freight train 10 that has traveled from Hokkaido to Honshu via the Seikan tunnel, the conventional freight train 2 of the conventional freight train 1 is transferred from the trajectory conversion section P ₂ on the Honshu side. In carrying out, the same method as described above can be adopted.

In the different-gauge track train moving system in the embodiment described above, the narrow gauge portion 31 of the traverser 30 is provided so as to be branched from the standard gauge portion 32. Therefore, the traverser 30 functions as a branching device, and the Shinkansen freight car. After the conventional line freight car 2 mounted in the eleventh vehicle body 12 is carried out, the conventional line freight train 1 can be caused to travel in a direction branched from the standard gauge L _S.

[Reference example]
Next, the different-orbit track train moving system in the reference example will be described with reference to FIGS. 11 and 12. This inter-gauge track train moving system employs a train loading / unloading vehicle 40 instead of the traverser employed in the first embodiment, and other configurations are substantially the same as those in the first embodiment. Are identical. Accordingly, the same components as those in the first embodiment will be described with the same reference numerals as those in the first embodiment.

  In this intergalactic track train moving system, as shown in FIGS. 11 and 12, a train loading / unloading vehicle 40 is arranged between the Shinkansen freight train 11 and the Shinkansen locomotive 10a of the Shinkansen freight train 10. The train loading / unloading vehicle 40 includes a loading / unloading track 41 and a loading / unloading exit 42 for loading the conventional railway wagon 2 from the Shinkansen railway 11 and the conventional railway wagon 2. It is.

The carry-in / out track 41 of the train carry-in / out vehicle 40 is arranged at an interval corresponding to the inter-rail dimension (1067 mm) of the narrow gauge L _N so that the conventional railway wagon 2 can run. One end of the carry-in / out track 41 is connected to a rail 12 a provided in the vehicle body 12 of the Shinkansen freight car 11, and the other end of the carry-in / out track 41 is on the side of the train carry-in / out vehicle 40. It is connected to the loading / unloading port 42 provided.

  Subsequently, with reference to FIG. 11 and FIG. 12, a method of bringing the conventional train wagon 2 into the Shinkansen freight car 11 (train delivery method) and a method of carrying out the conventional train wagon 2 from the Shinkansen freight car 11 (train delivery method). ).

<Train delivery method>
First, a method for carrying the conventional freight car 2 of the conventional freight train 1 into the Shinkansen freight car 11 of the Shinkansen freight train 10 will be described with reference to FIG. In the following explanation, the conventional line freight car 2 of the conventional freight train 1 that has traveled from Hokkaido to Honshu is carried into the Shinkansen freight car 11 of the Shinkansen freight train 10 in the trajectory conversion section P ₁ on the Hokkaido side. The method of doing this will be illustrated.

First, as shown in FIG. 11 (a), advancing the Shinkansen freight trains 10 from Hokkaido side orbital transfer portion P ₁ of the Hokkaido side. And as shown in FIG.11 (b), the loading / unloading exit 42 of the train loading / unloading vehicle 40 arrange | positioned between the Shinkansen freight train 11 and the Shinkansen locomotive 10a of the Shinkansen freight train 10, and the narrow gauge L on the Hokkaido side By aligning _N and _N , a continuous narrow gauge (curved trajectory) is formed.

Next, the conventional line freight train 1 is caused to travel from the narrow gauge L _N on the Hokkaido side toward the loading / unloading exit 42 of the train loading / unloading vehicle 40. At this time, the conventional line locomotive 3 is positioned on the Hokkaido side by reversing the traveling direction of the conventional line freight train 1, and the conventional line locomotive 3 is pushed to the Honshu side to run. To. Then, as shown in FIG. 11 (c), the conventional railway wagon 2 is sequentially loaded onto the loading / unloading track 41 of the train loading / unloading vehicle 40 and the rail 12 a of the Shinkansen railway 11, and the conventional railway wagon 2 is moved to the Shinkansen railway. 11 in the vehicle body 12.

Next, after the conventional line wagon 2 is completely carried into the vehicle body 12 of the Shinkansen freight car 11, the conventional line locomotive 3 is separated from the conventional line wagon 2 as shown in FIG. By reversing the traveling direction of the vehicle 3, the conventional locomotive 3 is returned onto the narrow gauge L _N on the Hokkaido side via the loading / unloading track 41 of the train loading / unloading vehicle 40. After that, as shown in FIG. 11 (e), the Shinkansen freight train 10 in which the conventional freight car 2 is mounted on the Shinkansen freight car 11 is caused to travel toward Honshu.

In addition, when the conventional railway freight train 2 of the conventional railway freight train 1 that has traveled from Honshu to Hokkaido is carried into the Shinkansen freight railway 11 of the Shinkansen freight train 10 at the trajectory conversion section P ₂ on the Honshu side. A method similar to the above method can be employed.

<Train unloading method>
Next, a method for carrying out the conventional railway freight car 2 of the conventional railway freight train 1 from the Shinkansen railway freight car 11 of the Shinkansen railway freight train 10 will be described with reference to FIG. In the following explanation, in the trajectory conversion section P ₁ on the Hokkaido side, the train freight train 11 of the Shinkansen freight train 10 that traveled from Honshu to Hokkaido via the Seikan tunnel will be replaced by the presence of the conventional freight train 1. Let us exemplify a method of carrying out the incoming train 2.

First, as shown in FIG. 12A, the Shinkansen freight train 10 that has traveled on the standard rail L _S in the Seikan Tunnel is entered into the Hokkaido-side track conversion section P ₁ . And as shown in FIG.12 (b), the loading / unloading exit 42 of the train loading / unloading vehicle 40 arrange | positioned between the Shinkansen freight train 11 and the Shinkansen locomotive 10a of the Shinkansen freight train 10, and the narrow gauge L on the Hokkaido side By aligning _N and _N , a continuous narrow gauge (curved trajectory) is formed.

Next, as shown in FIG. 12 (c), the conventional line locomotive 3 placed on the narrow gauge L _N on the Hokkaido side is transferred from the loading / unloading exit 42 of the train loading / unloading vehicle 40. The conventional line locomotive 3 is connected to the Hokkaido side end of the conventional line wagon 2 mounted inside the Shinkansen freight car 11. Then, as shown in FIGS. 12 (d) and 12 (e), the conventional line wagon 2 is pulled from the Shinkansen wagon 11 by pulling the conventional line wagon 2 to the Hokkaido side by the driving force of the conventional line locomotive 3. Take it out. Thereafter, the conventional freight train 1 is driven toward Hokkaido.

In addition, from the Shinkansen freight train 11 of the Shinkansen freight train 10 that has traveled from Hokkaido to Honshu via the Seikan Tunnel, the conventional freight train 2 of the conventional freight train 1 is transferred from the trajectory conversion section P ₂ on the Honshu side. When carrying out, the same method as the above method can be adopted.

In the different-gauge track train moving system described above, a continuous train can be obtained by running the Shinkansen freight train 10 and aligning the loading / unloading port 42 of the train loading / unloading vehicle 40 and the narrow gauge L _N. A narrow gauge can be constructed. And the conventional line freight car 2 can be carried into the inside of the Shinkansen freight car 11 via the carry-in / out opening 42 and the carry-in / out track 41 of the train carry-in / out vehicle 40 (see FIG. 11). Therefore, the conventional railway wagon 2 can be easily and quickly mounted on the Shinkansen railway freight car 11 without using a jack or the like, so that the conventional railway wagon can be used in a different-gauge trajectory that shifts from the narrow gauge L _N to the standard gauge L _S. 2 travel time can be greatly shortened.

Moreover, in the different-gauge track train moving system demonstrated above, it runs continuously by running the Shinkansen freight train 10 and aligning the loading / unloading exit 42 of the train loading / unloading vehicle 40 and the narrow gauge L _N. One narrow gauge can be constructed. And the conventional line freight car 2 can be carried out from the Shinkansen freight car 11 via the carry-in / out exit 42 and the carry-in / out track 41 of the train carry-in / out vehicle 40 (see FIG. 12). Therefore, since the conventional railway wagon 2 can be easily and quickly carried out from the Shinkansen railway freight car 11 without using a jack or the like, the conventional railway wagon can be moved in a different-gauge trajectory that shifts from the standard gauge L _S to the narrow gauge L _N. 2 travel time can be greatly shortened.

1 Conventional Line Freight Train 2 Conventional Line Freight Car (Railway)
2a Wheel 3 Conventional locomotive (railroad train locomotive)
10 Shinkansen freight train 10a Shinkansen locomotive (freight train locomotive)
11 Shinkansen wagons (freight trains)
12 Car body (train mounting part)
12a rail 20 traverser 21 narrow gauge part (first track part)
22 Standard gauge part (second track part)
30 Traverser 31 Narrow gauge part (first orbit part)
32 Standard track part (second track part)
40 Train loading / unloading vehicle 41 Loading / unloading track 42 Loading / unloading exit L _N Narrow gauge (predetermined track)
L _S standard gauge (specific orbit)

Claims (1)

A railway train composed of a plurality of railway vehicles and traveling on a predetermined track;
A freight train that travels on a specific track having a gauge different from the predetermined track, including a train mounting portion that is mounted in a state where the railcar is connected,
A freight train locomotive connected to the freight train and driving the freight train;
A locomotive for a railroad train connected to a railroad train traveling on a predetermined track and driving the railroad train;
A traverser that uses these trains and locomotives to both carry in the railroad train to the train mounting portion of the freight train and carry out the railroad train mounted on the train mounting portion. Rail train loading / unloading that realizes both the loading of the railroad train into the train mounting portion of the freight train and the loading of the railroad train mounted on the train mounting portion, using a rail track train moving system. A method,
The traverser includes a first track portion having the same gauge size as the predetermined track, and a second track portion having the same track size as the specific track on which the freight train travels, and the first track portion; A second track portion is provided in parallel;
The end of the predetermined track and the end of the specific track face each other on the same line and the traverser is disposed therebetween,
The first track portion is provided at a position higher than the second track portion, and the height of the first track portion from the ground is set on the train of the freight train placed on the second track portion. It is set to be the same as the height of the rail of the part from the ground,
The traverser allows the end of the predetermined track, the end of the specific track, and the first track portion to be aligned on the same line, the end of the predetermined track, the end of the specific track, and the second track portion. Are aligned on the same line, and the rail of the freight train that has entered the specific track, the first track portion of the traverser, and the predetermined track are continuous one predetermined. The rail train is loaded into the train mounting portion of the freight train with a track, and the rail train mounted on the train mounting portion is carried out,
At the time of carrying in, the freight train locomotive is put in a standby state on the second track portion of the traverser,
A railroad train carrying-in / out method, wherein the railroad locomotive is placed in a standby state on the first track portion of the traverser during the carry-out.

Images