阅读说明：本技术 可提升的承载装置、轨道车辆、敞车 (Liftable bearing device, rail vehicle and gondola car ) 是由 弗朗茨·布卢姆 霍斯特·弗斯尔 于 2019-08-02 设计创作，主要内容包括：本发明涉及一种可提升的承载装置,用于以装载物来装载轨道车辆,具有：承载框架,其具有纵梁,纵梁以朝向彼此的内侧彼此面向延伸并且纵梁彼此连接,承载框架在纵梁长度一部分上具有用于装载物的在横向于纵梁的最大宽度范围内能够行驶的第一支撑件；用于升降装置的容纳部位；用于将承载装置直接放置在集散站地面上的撑立面；其中,设有用于装载物的第二支撑件,其被布置在第一支撑装置的臂上或臂之间；臂在用于装载物的第一支撑件的可行驶宽度之外布置在枢转支承件上；臂的长度选择为,使得用于装载物的第一支撑件在臂的第一枢转位置中通过第二支撑件以可行驶的方式延长,并且第二支撑件在臂的第二枢转位置中相对于承载框架的第一支撑件被提升。(The invention relates to a liftable carriage for loading a rail vehicle with a load, comprising: a carrying frame having longitudinal beams which extend facing each other with their inner sides facing each other and which are connected to each other, the carrying frame having, over a part of the length of the longitudinal beams, a first support for loads which is travelable in the maximum width transversely to the longitudinal beams; a receiving portion for the lifting device; the supporting surface is used for directly placing the bearing device on the ground of the terminal; wherein a second support for the load is provided, arranged on or between the arms of the first support means; the arm is arranged on the pivot support outside the width of travel of the first support for the load; the length of the arm is selected such that the first support for the load is extended in a drivable manner in the first pivoted position of the arm by the second support and the second support is lifted in the second pivoted position of the arm relative to the first support of the carrying frame.)

1. A liftable carrier device (1) for loading a rail vehicle (2) with a load (3) by means of a lifting device, the carrier device having:

a carrying frame (8) having at least two longitudinal beams (4) which extend facing each other with their inner sides facing each other and which are connected to each other, wherein the carrying frame (8) has a first support (16) for loads which is drivable over a maximum width transversely to the at least two longitudinal beams (4) at least over a part of the length of the at least two longitudinal beams (4), preferably over the vertically lower end of the longitudinal beams (4),

at least one receiving point for a lifting device, in particular a receiving bucket (5),

a supporting surface (6) used for directly placing the bearing device (1) on the ground (7) of the collecting and distributing station,

it is characterized in that the preparation method is characterized in that,

at least one second support (17) for the load (3) is provided, which is arranged on or between the arms (12) of the first support means,

the arm (12) is arranged on the pivot support (13) beyond the width of travel of the first support (16) for the load (3), and

the length of the arm (12) is selected such that the first support (16) for the load is extended in a drivable manner by the at least one second support (17) in the first pivoted position of the arm (12), and the at least one second support (17) is lifted relative to the first support (16) of the carrying frame (8) in the second pivoted position of the arm (12).

2. The carrying arrangement according to claim 1, wherein the arm (12) is pivotable into the second pivot position by lowering the carrying arrangement (1) onto the rail vehicle (2), in particular into a hopper (9) of a gondola.

3. Load carrying device according to any one of the preceding claims, wherein the arms (12) are arranged inside the longitudinal beam (4) or outside the outer side of the longitudinal beam.

4. Load carrying device according to any one of the preceding claims, wherein the pivot bearing (13) of the arm (12) is arranged on the longitudinal beam (4) on an end region of the longitudinal beam (4) facing away from the first support (16), preferably on an end region of the longitudinal beam (4) which is at the top in the vertical direction.

5. Load carrying device according to at least one of the preceding claims, wherein the second support (17) of the at least one first support device (4) is configured in the form of a load carrying surface or in the form of a plurality of struts.

6. Load carrying device according to at least one of the preceding claims, wherein the load carrying device (1) has a pivotable device for detachably locking the arm (12), preferably for detachably locking the arm (12) to the longitudinal beam (4).

7. Load carrying device according to at least one of the preceding claims, wherein the load carrying device (1) has at least one first support device and at least one second support device with at least one third support (18) for a load, wherein the first and second support devices can be loaded with a load (3) independently of one another, preferably providing that the third support (18) of the second support device is configured in the form of a load-carrying surface and/or in the form of a plurality of struts.

8. The carrying device according to the preceding claim, wherein the second support device is pivotably supported relative to the carrying frame (8), preferably relative to the first support (16) of the carrying frame (8).

9. The carrying device according to the preceding claim, wherein the first support (16) is substantially horizontally extendable in a drivable manner by the at least one third support (18) in the first pivoted position of the second support device, and the at least one third support (18) is arrangeable at an oblique angle relative to the first support of the carrying frame (8) in the second pivoted position of the second support device.

10. The carrying device according to any one of claims 7 to 9, wherein the third support (18) is configured to be variable in length.

11. Load carrying device according to at least one of the preceding claims, wherein the arms (12) have at least partially a curved or bent course.

12. The carrying device according to the preceding claim, wherein the third support (18) is variable in length by means of at least one push-out member (18', 18 "), preferably lockable in at least one push position.

13. A rail vehicle (2), in particular a gondola car, having at least one carrying device (1) according to at least one of the preceding claims.

14. Truck with a hopper (9) and at least one carrier device (1) according to at least one of claims 1 to 12, wherein the carrier device (1) is at least partially arranged within the hopper (9).

Technical Field

The invention relates to a liftable support device having the features of the preamble of claim 1, and to a rail vehicle, in particular a gondola, having such a support device.

Background

A carrier of the type described is available from WO 2016/141399 a 1.

With such a load carrier it is possible to carry loads in various forms, the load itself not having to be directly hoistable, since the load carrier itself is hoistable. The load may be, for example, a vehicle (e.g., semi-trailer, tractor, bus) or a non-moving load (e.g., container).

In the present disclosure, a "receiving position" is understood to be a position of the at least one support device in which loading or unloading of the carrier device takes place. In the receiving position, the at least one support device is oriented substantially horizontally, and thus after loading with the load, the load is also oriented substantially horizontally. A "loading position" is understood to mean a position of the at least one support device in which the load is located on the rail vehicle together with the support device after the end of the loading process. In the stowed position, the vehicle may be oriented horizontally or obliquely depending on the configuration of the support.

In a carrying device of the generic type, a part of the loading space between the longitudinal beams of the first supporting device is claimed.

Disclosure of Invention

The object of the invention is to provide a support device of the generic type and a rail vehicle, in particular a gondola, having such a support device, for which an enlarged loading space is provided.

This object is achieved by a support device having the features of claim 1 and a rail vehicle, in particular a gondola, having such a support device. Advantageous embodiments of the invention are defined in the dependent claims.

The invention relates firstly to a liftable carrier device for loading a rail vehicle with a load by means of a lifting device. The support device has a support frame which in turn has at least two longitudinal supports which extend with their inner sides facing each other and which are connected to each other. The longitudinal beams of the support frame can be at least partially flat and/or profiled, for example with a substantially rectangular cross-sectional profile.

The support frame has, at least over a part of the length of the at least two longitudinal beams, a first support for loads that is drivable in a maximum width transversely to the at least two longitudinal beams. The longitudinal beams can be connected to one another via a drivable first support. The first support element, which can be driven, can be arranged at the vertically lower end of the longitudinal member.

The support frame also has at least one receiving point for the lifting device, in particular a receiving bucket. The receiving bucket is preferably configured for the gripping edge of a so-called "spreader", which can be mounted on a crane or a so-called "reach stacker". Particularly preferably, the receiving pockets are arranged in the upper end region of the carrying frame.

Since the first support means for the load have arms and at least one second support for the load is arranged at or between the arms, the distance of the pivot axis about which the first support means can pivot relative to the longitudinal beams of the carrying frame can be selected substantially independently of the dimensions of the second support. Furthermore, the path described by the second support during pivoting can be influenced thereby. The arms may extend at least partially substantially straight. The arms can be at least partially flat and/or profiled, for example with a substantially rectangular cross-sectional profile. The second support may be arranged at the arm at an angle. The orientation of the second support relative to the first support can thus be determined, for example, for a particular pivot position of the arm.

Since the arms are arranged on the pivot bearing outside the width of the first support for the load, the clear width of the connection between the longitudinal beams of the support frame, which is substantially achievable by the width of the first support, is not reduced by the arms.

The longitudinal beams of the carrying frame can be spaced apart from one another so that the carrying device can be easily loaded with vehicles (e.g. semitrailers, tractors, buses) or non-drivable goods (e.g. containers). Preferably, the uniform clear width (extending in the longitudinal direction) between the two longitudinal sides of the carrying frame, i.e. for example the possible travelable width of the first support, is at least about 2600 mm. The outer width, i.e. the distance of the outer sides of the stringers of the carrier frame, may be, for example, about 3000 mm.

By selecting the length of the arm such that the first support for the load is extended in a travelable manner in the first pivot position of the arm by the at least one second support and the at least one second support is raised in the second pivot position of the arm relative to the first support of the carrying frame, different possibilities for loading of the carrying device can be obtained. In particular, different possibilities of loading the first support and/or the second support are available. For example, it is possible to load (support) a load on the first support member without having to load the second support member with the load. It is also possible to load (support) loads on both the first support and the second support. In the first pivot position of the arm, travel of the first support may take place via the second support. The second support may be connected substantially horizontally (flatly) to the first support in the first pivoted position of the arm.

Since the second support is pivotable between the first pivot position and the second pivot position, it is possible to adapt the running rail formed by the first support and the second support to a predetermined contour, for example a standing surface or a bed of a railway truck.

Provision is made for the carrier device to have a support surface for placing the carrier device directly on the ground of the terminal. No fixed carrier structure is thus required for the placement and possible travel of the carrier, which can be provided as a special fitting in each terminal.

In particular, it is preferably provided that the arm can be pivoted into the second pivot position by the lowering when the support device is lowered onto the rail vehicle, in particular when lowered into the hopper of a gondola car. A part of the first support means (for example the second support) rests on the rail vehicle (for example on a container pin of the rail vehicle) when lowered. This abutment remains present during further lowering, which leads to the above-mentioned pivoting of the arm relative to the carrying frame of the support device.

It can be advantageous for the arms to be arranged on the inside or on the outside of the longitudinal beam.

By arranging the arms outside the inner side of the stringers, a structurally simple solution to the construction and arrangement of the arms is obtained, in which solution the uniform clear width (w) between the stringers of the carrying frame, which is achieved by the width of the first support, is not reduced by the arms. The arms can be arranged here substantially completely outside the outer side of the longitudinal beam.

Even when the arms are arranged inside the longitudinal beams, it is possible to achieve that the uniform clear width between the longitudinal beams of the support frame, which is achieved by the width of the first support, is not reduced by the arms. This can be achieved, for example, by: the longitudinal beams of the carrying frame have a bend in the region of the upper end (in the region of the end of the longitudinal beam facing away from the first support) outwards (pointing away from the first support). In another embodiment, the arms may be arranged at least partially inside and/or above the longitudinal beams of the load-bearing frame.

It can be advantageous if the pivot bearing of the arm is arranged on the longitudinal beam at an end region of the longitudinal beam facing away from the first support. The pivot bearing can be arranged on an end region of the longitudinal beam which is vertically upper. By this arrangement of the pivot bearing of the arm, the horizontal distance of the second support from the first support can be increased when the first support means is pivoted. If the carrying device is arranged (at least partially) in the bed of the gondola car when the carrying device is used together with a railway truck, it can be provided that the pivot bearing and possibly also the arm are located outside the bed by arranging the pivot bearing of the arm on the upper end region of the longitudinal beam. The available position in the hopper can thus be optimally utilized.

It can be advantageous if the second support element of the at least one first support device is designed in the form of a bearing surface or in the form of a plurality of struts. In the case of the construction of the second support element in the form of a plurality of struts, it can be provided that the supported load, for example a tire of a vehicle, projects partially between the struts.

It can be advantageous if the carrier device has a pivotable device for the locking arm. This locking may be accomplished by releasable attachment of the arm to the stringer, for example by means of a bolt. The arm can be fixed in the first pivot position of the first support means. The length of travel possible of the first support by the second support can be determined independently of the support surface of the carrying device when the first support device is locked in the first pivot position. The support device can thus be used as a flat loading surface, for example when used with a railway truck, like a railway flatcar. Of course, the load bearing device may also be used with a railway flatcar.

It can be advantageous if the carrying device has at least one first support means and at least one second support means for at least one third support means for the load. The first and second support means may be loaded with the load independently of each other. In this case, it can be provided that the second support of the first support device can be arranged on a first end of the first support, and the third support of the second support device can be arranged on a second end of the first support (opposite the first end).

It can be advantageous here for the second support device to be pivotably mounted relative to the support frame. In this case, the second support device can be pivotably supported relative to the first support of the carrying frame. The pivot bearing supporting the second support device can be arranged here on the second end side of the first support.

In this case, it can be advantageous if the first support element is extended in the first pivot position of the second support device in a drivable manner substantially horizontally by the at least one third support element. The third support member may thus be attached substantially flat to the first support member. In this case, it can be provided that the third support ends substantially flush with the longitudinal beams of the support frame in the first pivot position (possibly with the exception of ramp-like projections). When using a carrying device with a railway truck, it can thus be possible, for example, that the third support of the second support device together with the first support of the carrying frame can be arranged substantially completely in the bed of the truck.

It can also be advantageous here if the at least one third support can be arranged at an oblique angle relative to the first support of the carrying frame in the second pivoted position of the second support device. This makes it possible to adapt the running rail formed by the first support and the third support to a predetermined contour, for example a support surface or a hopper of a railway truck.

It can be advantageous for the second supporting device that the third support of the second supporting device is configured in the form of a bearing surface and/or in the form of a plurality of struts. In the case of the construction of the third support element in the form of a plurality of struts, it can be provided that the supported load, for example a tire of a vehicle, projects partially between the struts.

It can be advantageous for the second support means that the third support is designed to be variable in length. Hereby it is achieved that the length of the third support member is adapted to the load. The third support may be variable in length between a reduced length state and at least one increased length state. In this case, it can be provided that the third support ends substantially flush with the longitudinal beams of the support frame in the first pivot position in the reduced length state (optionally with the exception of the ramp-like projection).

In this case, it can be advantageous if the third support element is variable in length by means of at least one ejection element. A laterally projecting protrusion can be arranged on the at least one ejection member. In the retracted position, the at least one ejector member may be stowed substantially completely (except for the protruding tab if necessary) in the base of the third support. In a preferred embodiment, the third support element has two telescopically extendable ejection members nested within one another. Provision can be made that the ejection element can be locked in at least one ejection position.

Drawings

Embodiments of the invention are discussed with the aid of the figures. The figure is as follows:

figures 1a-e are isometric, top, first and second side and front views of a carrier according to the invention in a first configuration,

figures 2a-e are isometric, top, first and second side and rear views of a carrier according to the invention according to figure 1 in a second configuration,

fig. 3a-c, 3d are a sequence of the loading process of a rail vehicle in the form of a gondola and a side view after the completion of the loading process, here a load in the form of two tractors,

fig. 4a-c, 4d are a sequence of loading processes of a rail vehicle in the form of a gondola and a side view after the completion of the loading process, here a load in the form of a semitrailer,

fig. 5a-b are a sequence of a loading process of a rail vehicle in the form of a gondola, here a load in the form of a transport means.

Detailed Description

Fig. 1a shows an isometric view of an embodiment of a carriage 1 according to the invention in a first configuration for loading a rail vehicle 2 with a load 3 by means of a receiving bucket 5 by means of a lifting device, not shown. The configuration shown corresponds to the accommodated position.

The support device 1 has a support frame 8 with two longitudinal beams 4, which extend with their inner sides facing each other and which are connected to each other.

The support frame 8 has, at the vertically lower end of the longitudinal beams 4, over a part of the length of the two longitudinal beams 4, a first support 16 for the load 3, which is movable over a maximum width transversely to the two longitudinal beams 4.

First support means for the load 3 are also provided, which have pivotably supported arms 12 on the carrying frame 8, between which arms a second support 17 for the load 3 is arranged.

The arm 12 is arranged on the pivot support 13 outside the travelable width of the first support 16 for the load 3. In the present exemplary embodiment, the pivot bearing 13 is located partly within the profiled section of the longitudinal beam 4 and partly on the outer side of the longitudinal beam 4.

The length of the arm 12 is selected such that the first support 16 for the load is extended in a drivable manner in the first pivoted position of the arm 12 shown in fig. 1a-e by means of the second support 17. The second support 17 is connected substantially flat to the first end of the first support 16. A second support device having a third support 18 is connected at the second end-side end of the first support 16. The third support is shown in a first pivot position in which it is substantially flat connected to the first support 16.

As shown, the second support 17 can be extended by an extension 17' in the direction of the first support 16. This allows an elongation of the supporting surface of the second support 17, in particular in the second pivot position shown in fig. 2 of the first supporting means. This is very useful for transporting vehicles having more than two axles.

For the second support means, it is advantageous if the third support 18 is constructed as shown with a variable length. Whereby the length of the third support member 18 can be adapted to the load 3. The third support 18 is here variable in length between a reduced length state (see fig. 1d) and an increased length state (see fig. 1 a-c). The length variability is achieved in the exemplary embodiment shown by two telescopically extendable ejection elements 18', 18 ″ which are nested one inside the other.

In the embodiment shown, the second and third support members 17, 18 are configured in the form of load-bearing surfaces. They may also be constructed in the form of a plurality of struts, unlike those shown.

In the plan view of fig. 1b, it can be seen that the carrier 1 has a continuous clear width W which is not limited by the arms 12 (see fig. 1e), so that a continuously drivable running track is obtained.

The first side view of fig. 1c shows the first and second support means in their first pivot positions, respectively. In this state, the support device 1 can be positioned directly upright on the terminal floor 7, for example via the support surface 6, and can be driven from both sides.

In this embodiment, the pivot bearing 13 of the arm 12 is located in the end region of the longitudinal beam 4 which is vertically upper.

In the second side view of fig. 1d, the second supporting means are in a reduced length state, which is produced by the substantially complete movement in of the ejection members 18', 18 ". The third support 18 of the second support device ends essentially flush with the end-side end of the longitudinal beam 4, except for the ramp-like projection.

In the front view of fig. 1e, it can again be seen that the carrier 1 has a continuous clear width W which is not limited by the arms 12, so that a continuously drivable running track is obtained. In the present exemplary embodiment, the arms 12 are located partially within the profiled section of the longitudinal beam 4 and partially completely on the outside of the longitudinal beam 4.

Fig. 2a shows an isometric view of the embodiment of the carrier 1 according to fig. 1 in a second configuration, in which the first and second support means are both in the second pivot position. This second configuration corresponds to a state of the carrying device 1 which can itself be brought about by placing the carrying device 1 with the lifting device into the hopper 9 of a rail vehicle 2 which is designed as a gondola. The configuration shown corresponds to the loading position.

The second support 17 is raised relative to the first support 16 of the carrying frame 8.

The third support 18 of the second support device is arranged inclined relative to the first support 16 and projects beyond the end-side end of the longitudinal beam 4 on account of the elongation by the push-out members 18', 18 ″.

It can be seen that in this configuration, the arm 12 is in a raised position compared to the configuration shown in figure 1. In this configuration, openings 14 for bolts, not shown, and receptacles 15 for the arms 12 can be seen, which serve to detachably lock the arms 12 to the longitudinal beams 4.

The first side view of fig. 2c shows the first and second support means in their second pivot positions, respectively. Since the second support means is in the length-increased state here, which is obtained by a substantially complete removal of the push-out member 18', 18 ″, the third support member 18 is pivoted from its first pivot position into its second pivot position by being placed into the hopper 9 of the rail vehicle 2 configured as a gondola.

In the second side view of fig. 2d, the second support means is in a reduced length state, which is caused by the push-out members 18', 18 "being moved substantially completely in. Since the insertion into the hopper 9 of the rail vehicle 2, which is designed as a gondola car, does not result in a pivoting of the third support 18 of the second support device, the third support is held in the first pivoted position.

Fig. 3a-c show a sequence of loading processes of a rail vehicle 2 in the form of a gondola, here a load in the form of two tractors. The load in the form of two tractors rests here on wheels on the first support 16, the second support 17 and the third support 18, which is extended by the push-out means 18', 18 ".

Fig. 3a shows a state in which the carrier 1 is being lowered (or lifted out) by means of a not shown lifting device in the direction of the gondola, wherein there is no (or no longer any) contact between the carrier 1 and the gondola. The second support means is in an increased length state. The arm 12 of the first support means is in its first pivot position. The truck has a protruding pin 20 with which the first support surface 10 of the first support means and the bearing surface 11, 11 "of the second support means come into contact after the carrier 1 has been lowered further, as shown in fig. 3 b.

Fig. 3c shows the carrier 1 in a cross-section (section in the open wagon along the longitudinal extension of the open wagon) into the open wagon hopper 9. The second support 17 of the first support means and the third support 18 of the second support means have been pivoted into their second pivoted position by bringing the pin 20 into contact with the bearing surfaces 10, 11 of the first and second support means and lowering them. As shown, the second support member 17 (except for its extension 17' directed into the space inside the carrier 1) is completely outside and above the hopper 9, whereby the load 3 shown can be supported using the space outside the hopper 9. The third support 18 of the second support device is located partly outside the hopper 9 and partly inside the hopper 9 in an orientation extending obliquely to the horizontal. The first support 16 is located entirely within the hopper 9. The configuration shown corresponds to the loading position.

Fig. 3d shows the state of fig. 3c, but not in a sectional view, but in a side view. It can be seen that only the second support 17 (except for its extension 17' pointing into the inner space of the support device 1) and a part of the third support 18 protrude from the carrier 1 beyond the loading edge given by the truck side wall height. In the second pivot position of the arm 12, the carrier 1 is substantially completely above the loading edge of the hopper 9 when it is lowered into the hopper 9.

Fig. 4a-c show a sequence of loading processes of a rail vehicle 2 in the form of a gondola, here a semi-trailer, similar to the view of fig. 3a, with the difference that the third support member 18 of the second support device is in a reduced length state. No abutment of the abutment face 11 of the second support means against the pin 20 of the truck occurs. The second support means thus remains in the first pivot position when the carrying device 1 is lowered into the hopper 9 (see fig. 4c and 4 d). The extension 17' of the second support member 17 does not have to be used in this type of loads 3. The configuration shown corresponds to the loading position.

Fig. 4c shows that by using the arm 12, the distance between the second support member 17 and the pivot support member 13 (which defines the pivot axis of the pivoting movement of the second support member 17) can be selected such that the loading space between the longitudinal beams 4 can be used substantially over the entire clear width W and length for the load 3, and in particular in both the first and second pivot positions of the first support means.

Fig. 4d shows the state of fig. 4c, but not in a sectional view, but in a side view. It can be seen that from the carrier 1 only the second support 17 projects beyond the loading edge given by the height of the truck side wall. Since the second support means are not pivoted, the third support 18 is arranged completely in the hopper 9 together with the first support 16. In the second pivot position of the arm 12, the carrier 1 is substantially completely above the loading edge of the hopper 9 when it is lowered into the hopper 9.

Fig. 5a and 5b show a sequence of loading processes of a rail vehicle 2 in the form of a gondola with a carrier 1 on which a load 3 is placed in the form of a transport means. Loading in a flatcar manner with a substantially flat loading surface is produced.

The carrier device 1 can optionally be lifted onto the rail vehicle 2 by means of a lifting device, not shown, in the loaded state as shown or in the unloaded state.

In this application, the arm 12 is detachably fastened to a receptacle 15 of the longitudinal beam 4 by means of a screw and an opening 14 (see fig. 2c for this purpose).

Prior to loading, the carrier device 1 can be parked directly on the terminal floor 7 and loaded (by driving the transport vehicle) with the travelable load 3 in the form of a transport vehicle.

In contrast to fig. 3a and 4a, the support device 1 is offset in the longitudinal direction with respect to the truck bed 9 by an offset amount, so that, on further lowering, the pins 20 of the truck are caused to rest on a bearing surface 23 of the support frame 8, which is arranged on the end-side end of the support frame 8 facing the second support 17 (see fig. 5 b).

The fixed first support means with the second support surface 21 abuts the pin 20 of the truck. The second support surface 21 is arranged on the first support device according to the offset of the support device 1 in the longitudinal direction relative to the truck, which can be carried out using further extensions if necessary.

In the situation shown in fig. 5b, in which the lifting process is completed and the carrier device 1 is supported on the gondola, the carrier frame 8 with the bearing surfaces 23', 23 "is additionally supported on the gondola intermediate support 22 above the hopper 9.

The gondola loaded with a carrier 1 according to the invention can be driven continuously over its entire length in the flatcar application shown in fig. 5, in the sense that, for example, a plurality of transport vehicles can be driven onto the gondola one after the other. If a plurality of gondola cars are grouped together to form a train, the transport means can be driven from gondola car to gondola car if each gondola car that can be driven is loaded with a carrier device 1 according to the invention.

It is of course also possible to lift loads 3 that cannot be driven in by themselves, for example containers, onto the carrier device 1.

List of reference numerals:

1 bearing device

2 railway vehicle

3 load of goods

4 longitudinal beam

5 containing bucket

6 supporting surface of bearing device

7 ground of distributed station

8 bearing frame

9 open wagon hopper

10 first support surface of the first support device

11. 11' bearing surface of the second support means

12 arm

13-arm pivot support

14 opening for bolt

15 accommodating part for arm

16 first support

17 second support member

17' extension of the second support

18 third support

18' first ejector part of third support

18' third support member

19-towing vehicle

20 open wagon pin

21 second bearing surface of the first bearing means

22 gondola car middle support

23. 23 ', 23' bearing surface of a load-bearing frame

W continuous clear width