KR102619652B1 - Elevating and Sliding type rack rail structure of branch section for mountain railway vehicle - Google Patents

Abstract

The present invention relates to a lifting and sliding rack rail structure in a branch section for a mountain railway vehicle, and includes first and second branch racks branching from the main rack rail at the section where the branch begins among the branch sections of the track on which the mountain railway vehicle travels. By not only raising and lowering the rails so that they cross each other but also moving them in both directions of the track, the mountain railway vehicle can selectively use the corresponding branch rack rail depending on the track, but the running of the mountain railway vehicle is not interrupted by other branch rack rails that are not in use. It provides a lifting and sliding type rack rail structure for branch sections for mountain railway vehicles that do not operate.

Description

Elevating and sliding type rack rail structure of branch section for mountain railway vehicle}

The present invention relates to a lifting and sliding rack rail structure in a branch section for a mountain railway vehicle, and more specifically, to a first and a The second branch rack rails are raised and lowered across each other, as well as moved (or slid) to both sides, so that mountain railway vehicles can selectively use the corresponding branch rack rails depending on the travel track, and to ensure that running is not interrupted by other branch rack rails. This relates to the lifting and sliding rack rail structure of the branch section for mountain railway vehicles.

Generally, a train needs to branch from one track to another track to change its course while running.

In order to change the running path of the train, a switch is installed at the branch point of the track on which the train travels, and this switch is operated by a track switch to change the track.

This switch allows one track consisting of a pair of left and right rails to be separated into two tracks, allowing a running train to run along either one of the two tracks. The basic rail, tongue rail, It consists of crossings.

On the other hand, when railway vehicles operate in areas with strong slopes, such as mountain railways, the railway vehicles often slip on the lower part of the slope of the track, making operation difficult. To prevent the railway vehicles from slipping, the center of the track Rack gears are installed along the tracks, and pinion gears are installed on vehicles to correspond to the rack gears to prevent railroad vehicles from sliding down the slope and enable them to run stably on slopes.

This rack rail structure for mountain railway vehicles has been proposed through Registered Utility Model No. 20-0362089 (Reference 1), Public Patent No. 10-2018-0069196 (Reference 2), etc.

In addition, rack rails also exist in the branch section for mountain railway vehicles, and in the branch section, the main rack rail is also branched into first and second branch rack rails and formed as one piece.

However, although the pinion gear of the mountain railway vehicle must be engaged with either the first or second branch rack rail in the branch section, the first and second branch rack rails are formed integrally with the branch rack rail to be driven. There is a problem that mountain railway vehicles cannot run stably because they are not aligned accurately.

Therefore, there is a need to develop technology that can ensure driving stability by accurately engaging the mountain railway vehicle with the branch rack rail when traveling even in a branch section.

Reference 1: Registered Utility Model No. 20-0362089 Reference 2: Publication Patent No. 10-2018-0069196

Therefore, the present invention is intended to solve these problems, and the present invention is to provide a system in which, in a branch section of a track on which a mountain railway vehicle travels, when a mountain railway vehicle selectively uses the corresponding branch rack rail according to the travel track, it can travel by another branch rack rail. A lifting and sliding rack in the branch section for mountain railway vehicles that not only lifts and lowers the first and second branch rack rails that branch from the main rack rail at each other in the section where the branch begins so as not to be disturbed, but also moves (or slides) them on both sides. The purpose is to provide a rail structure.

In order to solve this technical problem, the present invention;

A pair of first and second branch rack rails provided at a section where the branch begins among the branch sections of the track for mountain railway vehicles, first and second lifting means for raising and lowering the first and second branch rack rails, and A base panel on which the first and second lifting means are installed, a horizontal transfer means for moving the base panel in both directions of the track, and the first and second lifting means so that the first and second branch rack rails cross lifting and lowering. A lifting and sliding type rack rail structure for a branch section for a mountain railway vehicle is provided, which includes a control unit that controls the horizontal transfer means so that the base panel moves horizontally in both directions of the track.

At this time, the first lifting means consists of a first cylinder in which a first rod moves forward and backward toward the front end of the first body; The rear end of the first body is fixed to the base panel, and the front end of the first rod is integrally fixed to the lower end of the first branch rack rail.

Additionally, the second lifting means includes a second cylinder in which a second rod moves forward and backward toward the front end of the second body; The rear end of the second body is fixed to the base panel, and the front end of the second rod is integrally fixed to the lower end of the second branch rack rail.

In addition, the first branch rack rail is integrally fixed to the upper surface of the first rail fixing plate, a lower side of the first rail fixing plate is hinged to the base panel by a 1_1 hinge pin, and the first rail The other lower side of the fixing plate is hinged to one end of the first lifting means by a 1_2 hinge pin, and the other end of the first lifting means is hinged to the base panel by a 1_3 hinge pin.

At this time, the first lifting means consists of a first cylinder in which the first rod moves forward and backward toward the front end of the first body, and the front end of the first rod of the first cylinder is 1_2 on the other lower side of the first rail fixing plate. It is hinged via a hinge pin, and the rear end of the first body of the first cylinder is hinged to the base panel via a 1_3 hinge pin.

And, when the first rod advances and the first rail fixing plate is in a horizontal state, the first branch rack rail is in a raised state, and when the first rod moves backward and the other side of the first rail fixing plate is lowered and inclined. The first branch rack rail is characterized in that it is in a lowered state.

In addition, the second branch rack rail is integrally fixed to the upper surface of the second rail fixing plate, a lower side of the second rail fixing plate is hinged to the base panel by a 2_1 hinge pin, and the second rail The other lower side of the fixing plate is hinged to one end of the second lifting means by a 2_2 hinge pin, and the other end of the second lifting means is hinged to the base panel by a 2_3 hinge pin.

At this time, the front end of the second rod of the second cylinder is hinged to the other lower side of the second rail fixing plate via the 2_2 hinge pin, and the rear end of the second body of the second cylinder is connected to the base panel by 2_3. It is characterized by being hinged via a hinge pin.

And, when the second rod advances and the second rail fixing plate is in a horizontal state, the second branch rack rail is in a raised state, and when the second rod moves backward and the other side of the second rail fixing plate is lowered and inclined. The second branch rack rail is characterized in that it is in a lowered state.

In addition, the horizontal transfer means consists of a third cylinder in which a third rod moves forward and backward toward the front end of the third body; The third body of the third cylinder is fixed to the sleeper, and the third rod is fixed to the lower part of the base panel.

According to the present invention, in the section where the branch begins among the branch sections of the track on which the mountain railway vehicle travels, the first and second branch rack rails that branch from the main rack rail are raised and lowered to cross each other and are moved in both directions of the track. By doing so, the mountain railway vehicle selectively uses the corresponding branch rack rail according to the travel track, but the running of the mountain railway vehicle is not interrupted by other unused branch rack rails, which has the effect of inducing stable running of the mountain railway vehicle.

In particular, according to the present invention, when the mountain railway vehicle travels on the main track, the first branch rack rail rises, and when the mountain railway vehicle travels on the branch track, the second branch rack rail rises so that the mountain railway vehicle travels on the track. This has the effect of allowing the branch rack rail to be used selectively and preventing driving from being interrupted by other branch rack rails.

Figure 1 is a perspective view showing the lifting and sliding type rack rail structure of a branch section for a mountain railway vehicle according to the present invention.
Figure 2 is a cross-sectional view of a branch line shown to explain the lifting and sliding rack rail structure of the branch section for mountain railway vehicles according to an embodiment of the present invention.
Figure 3 is a cross-sectional view of a branch line shown to explain the lifting and sliding rack rail structure of a branch section for a mountain railway vehicle according to another embodiment of the present invention.

Hereinafter, the features of the lifting and sliding rack rail structure of the branch section for mountain railway vehicles according to the present invention will be described in detail with reference to the attached drawings to understand the features.

Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor should appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of definability.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so at the time of filing this application, they can be replaced. It should be understood that various equivalents and variations may exist.

Referring to Figures 1 and 2, the lifting and sliding rack rail structure of the branch section for mountain railway vehicles according to the present invention branches off from the main rack rail at the section where the branch begins among the branch sections of the track for mountain railway vehicles and forms a branch section. The first and second branch rack rails (10, 20) connected to each subsequent rack rail cross each other and are raised and moved to the left and right, so that when the mountain railway vehicle travels on the main track, the first branch rack rail (10) rises. And, when the mountain railway vehicle travels on a branch track, the second branch rack rail (20) is raised so that the mountain railway vehicle can selectively use the branch rack rail according to the driving track, and is operated by other branch rack rails. It is a structure that prevents driving from being interrupted.

The present invention includes a pair of first and second branch rack rails (10, 20) provided at a section where the branch begins among the branch sections of a track for mountain railway vehicles, and the first and second branch rack rails (10, 20), first and second lifting means (30, 40) for elevating and lowering, a base panel (81) on which the first and second lifting means (30, 40) are installed, and a line connecting the base panel (81) The horizontal transfer means 80 moves in both directions, and the first and second elevating means (30, 40) are controlled to cross-elevate the first and second branch rack rails (10, 20), and the base It includes a control unit 50 that controls the horizontal transfer means 80 so that the panel 81 moves horizontally in both directions of the track.

Here, crossing is a concept in which the first and second lifting means (30, 40) act in opposite directions. For example, when the first branch rack rail (10) rises, the second branch rack rail (20) lowers. Conversely, this means that when the second branch rack rail 20 rises, the first branch rack rail 10 descends.

Therefore, the alternating operation of the first branch rack rail 10 and the second branch rack rail 20 occurs when the first elevating means 30 and the second elevating means 40 are driven. This is an operational relationship in which the second branch rack rails 20 rise and fall in opposite directions.

Meanwhile, the control unit 50 is configured to cross-control the first and second lifting means 30 and 40 and control the driving of the horizontal transfer means 80, and the line switch that controls the branch in the branch section is the It is desirable to perform the function of the control unit 50.

In addition, when the mountain railway vehicle travels on a track, the control unit 50 first controls the horizontal transfer means 80 so that the first or second branch rack rails 10 and 20 become the pinion gear of the mountain railway vehicle. After moving the base panel 81 horizontally to both sides of the track to a position where it can be engaged, it is preferable to alternately control the first and second lifting means 30 and 40.

Of course, the control unit 50 may control the first and second lifting means 30 and 40 first and control the horizontal transport means 80 as a second priority depending on the situation.

Hereinafter, the configuration of each part of the present invention will be described in detail.

First, in the branch section of the track on which the mountain railway vehicle runs, there are first and second running rails (1, 2) installed on the track at intervals to allow the user to select one of the two tracks to run on. First and second tongue rails 3 and 4 are provided.

These first and second running rails (1, 2) and first and second tongue rails (3, 4) are installed on sleepers (5) installed on the road surface of the branch section, and the first and second running rails Between (1, 2), that is, at the center of the branch section, first and second branch rack rails (10, 20) where the pinion gear of the mountain railway vehicle engages are provided.

Therefore, in the branch section of the track, the main rack rail (10a) is also structured to branch into the first and second branch rack rails (10 and 20).

In this case, it is preferable that the main rack rail (10a) is formed to become wider toward the section where the branch begins so that both the first and second branch rack rails (10, 20) can be stably connected.

Meanwhile, the first and second branch rack rails (10, 20) are raised and lowered to allow mountain railway vehicles to selectively use the corresponding branch rack rail according to the travel track and to prevent running from being interrupted by other branch rack rails. The first and second lifting means (30, 40) are installed on the upper part of the base panel (81).

At this time, first and second rack gears 11 and 21 are formed on the upper surfaces of the first and second branch rack rails 10 and 20, respectively, to engage with the pinion gear installed in the mountain railway vehicle.

In addition, the first lifting means 30 may be composed of a first cylinder 31 in which the first rod 31a moves forward and backward toward the front end of the first body 31b. The first cylinder 31 may be of various types, such as hydraulic or electric. In this first cylinder 31, the rear end of the first body 31b is fixed to the upper part of the base panel 81, and the front end of the first rod 31a is fixed to the lower end of the first branch rack rail 10. It is fixed as one piece.

Accordingly, the first cylinder 31 is driven by the control unit 50 to move the first rod 31a forward and backward, thereby raising and lowering the first branch rack rail 10.

In addition, the second lifting means 40 has the same structure as the first lifting means 30, and the second rod 41a is a second cylinder 41 that moves forward and backward toward the front end of the second body 41b. It can be configured. The second cylinder 41 may be of various types, such as hydraulic or electric. In this second cylinder 41, the rear end of the second body 41b is fixed to the upper part of the base panel 81, and the front end of the second rod 41a is fixed to the lower end of the second branch rack rail 20. It is fixed as one piece.

Accordingly, the control unit 50 can drive the second cylinder 41 to move the second rod 41a forward and backward to raise and lower the first branch rack rail 10.

In addition, the first and second elevating means (30, 40), in addition to cylinders that perform linear motion, can be used in various ways, such as a motor type, if they are configured to elevate the first and second branch rack rails (10, 20). can do.

Meanwhile, the base panel 81 on which the first and second lifting means 30 and 40 are installed is made of a square plate shape and can move in both left and right directions of the track. This base panel 81 can be installed on the upper side of the sleeper 5, and the base panel 81 can be moved in both left and right directions by the horizontal transfer means 80 installed on the sleeper 5.

At this time, the horizontal transfer means 80 may be composed of a third cylinder 82 in which the third rod 82a moves forward and backward toward the front end of the third body 82b. Like the first and second cylinders 31 and 41, the third cylinder 82 may be of various types, such as hydraulic or electric. The third body 82b of the third cylinder 82 is fixed to the sleeper 5, and the third rod 82a is fixed to the lower part of the base panel 81.

Accordingly, the control unit 50 can drive the third cylinder 82 to move the third rod 82a forward and backward, thereby moving the base panel 81 in both directions.

In addition, the third cylinder 82, which is the horizontal transfer means 80, is preferably provided on both lower sides of the base panel 81 as shown, but may also be provided on the lower left or right side of the base panel 81. possible.

Hereinafter, an operation example of the lifting and sliding type rack rail structure of a branch section for a mountain railway vehicle according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

First and second lifting means (30, 40) for raising and lowering a pair of first and second branch rack rails (10, 20) provided in the section where the branch begins among the branch sections of the track, and a base panel (81) The horizontal transfer means 80, which moves horizontally in both directions of the track, is operated by the control unit 50.

First, the control unit 50 controls the horizontal transfer means 80 to move the first or second branch rack rails 10 and 20 to a position where the pinion gear of the mountain railway vehicle can engage with the base panel 81. Move horizontally to both sides of the track.

Thereafter, the control unit 50 controls the first and second lifting means 30 and 40 to alternately lift and lower the first and second branch rack rails 10 and 20.

Specifically, the control unit 50 controls the first cylinder 31, which is the first lifting means 30, to advance the first rod 31a to vertically raise the first branch rack rail 10. In this case, at the same time, the second cylinder 41, which is the second elevating means 40, is controlled to move the second rod 41a backward and the second branch rack rail 20 is lowered vertically so that the mountain railway vehicle When driving, the pinion gear of the mountain railway vehicle is stably engaged with the first branch rack rail (10) and the driving can be prevented from being interrupted by the second branch rack rail (20).

On the contrary, when the control unit 50 controls the first cylinder 31, which is the first lifting means 30, to move the first rod 31a backward to vertically lower the first branch rack rail 10, At the same time, the second cylinder 41, which is the second elevating means 40, is controlled to advance the second rod 41a to vertically raise the second branch rack rail 20, so that when the mountain railway vehicle runs, the mountain railway The pinion gear of the vehicle is stably engaged with the second branch rack rail (20) and the driving can be prevented from being interrupted by the first branch rack rail (10).

Meanwhile, Figure 3 relates to a lifting and sliding rack rail structure of a branch section for a mountain railway vehicle according to another embodiment of the present invention.

According to this, a pair of first and second branch rack rails (10, 20) provided at the section where the branch begins among the branch sections of the track are raised and lowered by the first and second lifting means (30, 40).

At this time, the first branch rack rail 10 is integrally fixed to the upper surface of the first rail fixing plate 60, and one lower side of the first rail fixing plate 60 is attached to the base panel 81 with the 1_1 hinge. It is hinged by a pin 61, and the other lower side of the first rail fixing plate 60 is hinged to one end of the first lifting means 30 by a 1_2 hinge pin 62, and the first lifting means The other end of the means 30 is hinged to the base panel 81 by the 1_3 hinge pin 63.

This first lifting means 30 may be composed of a first cylinder 31 in which the first rod 31a moves forward and backward toward the front end of the first body 31b.

In this case, the front end of the first rod (31a) of the first cylinder (31) is hinged to the other lower side of the first rail fixing plate (60) via the 1_2 hinge pin (62), and the first cylinder (31) The rear end of the first body (31b) of (31) is hinged to the base panel (81) via the 1_3 hinge pin (63).

Of course, in order to support the 1_1 to 1_3 hinge pins (61, 62, 63), the first rail fixing plate (60) and the base panel (81) are provided with a plurality of hinge brackets (or supports) (64, 65, 66,67) must be provided in one piece.

Therefore, when the first cylinder 31 is driven by the control unit 50 to move the first rod 31a forward and backward, the other side of the first rail fixing plate 60 centers on the 1_1 hinge pin 61. It rotates up and down within a limited angle range, and the first branch rack rail 10 can be raised and lowered accordingly.

In this case, when the first rod (31a) advances and the first rail fixing plate (60) is in a horizontal state, the first branch rack rail (10) is raised, and the first rod (31a) moves backward to form the first rail fixing plate (60). When the other side of the rail fixing plate 60 is lowered and inclined, the first branch rack rail 10 is in a lowered state.

In addition, the second branch rack rail 20 is integrally fixed to the upper surface of the second rail fixing plate 70, and one lower side of the second rail fixing plate 70 is attached to the base panel 81 with a 2_1 hinge. It is hinged by a pin 71, and the other lower side of the second rail fixing plate 70 is hinged to one end of the second lifting means 40 by a 2_2 hinge pin 72, and the second lifting means The other end of the means 40 is hinged to the base panel 81 by the 2_3 hinge pin 73.

This second lifting means 40 may be composed of a second cylinder 41 in which the second rod 41a moves forward and backward toward the front end of the second body 41b.

In this case, the front end of the second rod 41a of the second cylinder 41 is hinged to the other lower side of the second rail fixing plate 70 via a 2_2 hinge pin 72, and the second cylinder 41 The rear end of the second body (41b) of (41) is hinged to the base panel (81) via the 1_3 hinge pin (73).

Of course, in order to support the 2_1st to 2_3rd hinge pins (71, 72, 73), hinge brackets (74, 75, 76, 77) are integrated into the second rail fixing plate (70) and the base panel (81). It must be equipped with

Therefore, when the second cylinder 41 is driven by the control unit 50 to move the second rod 41a forward and backward, the other side of the second rail fixing plate 70 centers on the 2_1 hinge pin 71. It rotates up and down within this limited angle range, and the second branch rack rail 20 can be raised and lowered accordingly.

In this case, when the second rod (41a) advances and the second rail fixing plate (70) is in a horizontal state, the second branch rack rail (20) is in a raised state, and the second rod (41a) moves backward to secure the second rail. When the other side of the fixing plate 70 is lowered and inclined, the second branch rack rail 20 is in a lowered state.

In the above, the rotation of the first and second rail fixing plates (60, 70) was explained as the other side rotating around one side, but the other sides of the first and second rail fixing plates (60, 70) are adjacent to each other. It should be understood that they are arranged symmetrically left and right.

In addition, the first and second lifting means (30, 40) can be used in various ways, such as by a motor, as long as they are configured to rotate the first and second rail fixing plates (60, 70) in addition to cylinders that perform linear motion. Design can be changed.

Hereinafter, an operation example of a lifting and sliding type rack rail structure in a branch section for a mountain railway vehicle according to another embodiment of the present invention will be described with reference to FIG. 3.

First and second lifting means (30, 40) for raising and lowering a pair of first and second branch rack rails (10, 20) provided in the section where the branch begins among the branch sections of the track, and a base panel (81) The horizontal transfer means 80, which moves horizontally in both directions of the track, is operated by the control unit 50.

First, the control unit 50 controls the horizontal transfer means 80 to move the first or second branch rack rails 10 and 20 to a position where the pinion gear of the mountain railway vehicle can engage with the base panel 81. Move horizontally to both sides of the track.

Thereafter, the control unit 50 controls the first and second lifting means 30 and 40 to alternately lift and lower the first and second branch rack rails 10 and 20.

Specifically, the control unit 50 controls the first cylinder 31, which is the first lifting means 30, to advance the first rod 31a to place the first rail fixing plate 60 in a horizontal state. When the first branch rack rail (10) is raised by rotating, at the same time, the second cylinder (41), which is the second elevating means (40), is controlled to move the second rod (41a) backward to the second rail fixing plate. The other side of (70) is rotated downward to lower the second branch rack rail (20), so that when the mountain railway vehicle is running, the pinion gear of the mountain railway vehicle is stably engaged with the first branch rack rail (10) and the second branch rack rail (20) is lowered. It is possible to prevent driving from being interrupted by the rail 20.

On the contrary, the control unit 50 controls the first cylinder 31, which is the first lifting means 30, to move the first rod 31a backward and rotate the other side of the first rail fixing plate 60 downward. When lowering the first branch rack rail (30), at the same time, the second cylinder (41), which is the second elevating means (40), is controlled to advance the second rod (41a) to advance the second rail fixing plate (70). ) is rotated to a horizontal state to raise the second branch rack rail (20), so that when the mountain railway vehicle is running, the pinion gear of the mountain railway vehicle is stably engaged with the second branch rack rail (20) and the first branch rack rail (10) ) can prevent driving from being interrupted.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations can be made by those skilled in the art in the technical field to which the present invention pertains without departing from the essential characteristics of the present invention. The scope of protection shall be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope shall be construed as being included in the scope of rights of the present invention.

10: First branch rack rail 20: Second branch rack rail
30: first lifting means 40: second lifting means
50: Control unit 60: First rail fixing plate
70: second rail fixing plate 80: horizontal transport means
81: Base panel

Claims (10)

Includes a pair of first and second branch rack rails branched from the main rack rail at the section where the branch begins among the branch sections of the track for mountain railway vehicles and connected to each rack rail after the branch section,
The first elevating means for elevating the first branch rack rail and the second elevating means for elevating the second branch rack rail are controlled by the control unit to alternately elevate the first and second branch rack rails, so that the mountain railway vehicle Depending on the driving line, the corresponding branch rack rail can be used selectively,
The horizontal transfer means for moving the base panel on which the first and second lifting means are installed to both sides of the track is controlled by the control unit to move horizontally in both directions of the track,
The first branch rack rail is integrally fixed to the upper surface of the first rail fixing plate, a lower side of the first rail fixing plate is hinged to the base panel by a 1_1 hinge pin, and the first rail fixing plate The other lower side of the is hinged to one end of the first elevating means by a 1_2 hinge pin, and the other end of the first elevating means is hinged to the base panel by a 1_3 hinge pin so that when the first elevating means operates, the The other side of the first rail fixing plate rotates up and down within a limited angle range around the 1_1 hinge pin and raises and lowers the first branch rack rail,
The second branch rack rail is integrally fixed to the upper surface of the second rail fixing plate, a lower side of the second rail fixing plate is hinged to the base panel by a 2_1 hinge pin, and the second rail fixing plate The other lower side of the is hinged to one end of the second elevating means by a 2_2 hinge pin, and the other end of the second elevating means is hinged to the base panel by a 2_3 hinge pin so that when the second elevating means operates, the 2_1 Lifting and sliding type rack rail structure in the branch section for mountain railway vehicles, characterized in that the other side of the second rail fixing plate rotates up and down within a limited angle range around the 1st hinge pin and raises and lowers the second branch rack rail. .
delete delete delete According to clause 1,
The first lifting means consists of a first cylinder in which a first rod moves forward and backward toward the front end of the first body,
The front end of the first rod of the first cylinder is hinged to the other lower side of the first rail fixing plate via a 1_2 hinge pin, and the rear end of the first body of the first cylinder is connected to the base panel by a 1_3 hinge pin. A lifting and sliding rack rail structure for a branch section for a mountain railway vehicle, characterized in that it is hinged through a.
According to clause 5,
When the first rod advances and the first rail fixing plate is in a horizontal state, the first branch rack rail is in a raised state. If the first rod moves backward and the other side of the first rail fixing plate is lowered and inclined, the first branch rack rail is in a raised state. A lifting and sliding rack rail structure in the branch section for a mountain railway vehicle, characterized in that the branch rack rail is in a lowered state.
delete According to clause 1,
The second lifting means consists of a second cylinder in which the second rod moves forward and backward toward the front end of the second body,
The front end of the second rod of the second cylinder is hinged to the other lower side of the second rail fixing plate via a 2_2 hinge pin, and the rear end of the second body of the second cylinder is connected to the base panel through a 2_3 hinge pin. A lifting and sliding rack rail structure for a branch section for a mountain railway vehicle, characterized in that it is hinged through a.
According to clause 8,
When the second rod advances and the second rail fixing plate is in a horizontal state, the second branch rack rail is raised. If the second rod moves backward and the other side of the second rail fixing plate is lowered and inclined, the second branch rack rail is in a raised state. A lifting and sliding rack rail structure in the branch section for a mountain railway vehicle, characterized in that the branch rack rail is in a lowered state.
According to clause 1,
The horizontal transfer means consists of a third cylinder in which a third rod moves forward and backward toward the front end of the third body;
A lifting and sliding rack rail structure in a branch section for a mountain railway vehicle, wherein the third body of the third cylinder is fixed to the sleeper, and the third rod is fixed to the lower part of the base panel.