FI92665C - Settlement Mechanism - Google Patents

Description

92665

Margin Transfer Mechanism - Transmissionsmekanism for betåck-Ning 5

The invention relates to a roof transfer mechanism in a covered railway carriage having roof sections connected to each other and / or to the carriage body in the closed position, at least one of which can be moved by the transfer mechanism from the closed position to the moving position and back the transmission mechanism comprising at least one drive means which, via the drive axle and the conversion mechanism connected thereto, drives the drive rods 15 and at least one drive provided on each side of the carriage via levers or the like.

The roof transfer mechanisms of the transfer roof wagon are described, for example, in publication FI-87332. In this type of construction in common use, the roof parts are moved to the movement position, i.e. the spreading position, and out of the roof parts to the closed position by means of hand-held handrails at the ends of the carriage. From the gearbox *, the movement is transmitted to the levers and rods raising and moving the roof part themselves, such as the pivot shafts according to patent application FI-913228. Here, the structure leading from the ends of the wagon through its center to the roof mechanisms of the roof on the sides of the wagon has the disadvantage of very long displacements of movement from the handrail to the gearbox, resulting in In addition, due to the end doors and other structures, there is no proper space at the ends of the railway carriage for handwheels or similar drives on all types of wagons.

92665 2 There are no structures in use that differ materially from this investment principle. For example, although SE-419 071 and U.S. Pat. No. 3,513,783 disclose locking mechanisms for railway car doors in which the operating device is in the doors themselves, this cannot in any way be applied to the use of the transfer cover transmission mechanism, since the transmission mechanism is part of the car body. , which cannot be used with a device with a separate transfer cover.

It is therefore an object of the invention to provide a margin transfer mechanism which has considerably shorter transfer travel distances than in known devices. Another object of the invention is to provide such a transfer mechanism with few joints and gears or the like, and thus to enable a simple and reliable structure. A third object of the invention is that any functional machine elements can be integrated into the drive shafts or rods and in particular without intermediate joints or the like in order to obtain a durable structure. A fourth object of the invention is to provide such a transfer mechanism in which the drive device is in such a position or position that it can be used even when the freight wagon is at the loading dock, whereby the access to the lower part of the wagon is limited. In addition, it is an object of the invention to provide such a structure which enables a low-cost transmission mechanism for railway carriages with different types of transfer covers.

The disadvantages described above can be eliminated and the above-mentioned objects are achieved by the roof transfer mechanism according to the invention, which is characterized by what is defined in the characterizing part of claim 1.

The main advantage of the invention is that the cover transmission mechanism in question consists of relatively short shafts 35 and rods which can be placed in a tight space, thus avoiding long transmission distances. Another advantage of the invention is that the power-transmitting machine members, such as gears or screws, are simple in construction, 92665 3 are few in number and that it is generally not necessary to use the articulated joints required for small angular changes in the rotating shafts in particular. Another advantage of the invention is that it is applicable to all types of freight wagons, regardless of whether they have ends, end doors, a center console or not a center console, or whether there are one or more or more types of transferable coverings.

The invention will now be described in detail with reference to the accompanying drawings.

Fig. 1 shows an axonometric view of a freight car with a center console, in which the roof transfer mechanism according to the invention is illustrated in principle.

Figure 2 shows axonometrically a first embodiment of a cover transfer mechanism according to the invention.

Figure 3 shows axonometrically another embodiment of a cover transfer mechanism according to the invention.

Fig. 4 shows the conversion mechanism of Fig. 3 in more detail in the same view.

Figure 1 shows a railway carriage 1 generally equipped with a center console 24, which may be of the type described in, for example, patent application FI-921928. Of course, the invention is not limited to use only in this type of railway carriage, but can be applied to any type of railway carriage, as will be described below. The railway carriage 1 has per se known roof parts 2 connected to each other and / or to the carriage body in the closed position, at least one of which is movable by the transfer mechanism 27 from the closed position to the moving position and back. The cover part applied in its movable position can be moved along running rails (not shown in the figures) in the longitudinal direction L of the carriage on or outside the cover part in each case in the closed position.

35 These transfer margins are known per se and are commonly used, and are therefore not described in more detail here.

92665 4

The cover transfer mechanism 27 typically comprises one drive means 3, such as a hand crank or the like, for each movable roof part. According to the invention, the drive means 3 is preferably detachable and / or pivotable inside a structure, such as a center console or a side beam, on the side 10 of the railway carriage, so that it does not increase the width of the carriage during travel. In the embodiments of the figures, this rotatable drive means 3 can be connected to the shaft 24 and thereby by means of a chain drive 25 or a similar belt drive or by a gear-tooth gear 10 or in another suitable manner. In this transmission, which increases the distance H, the drive means 3 is sufficiently above the side beam 12 of the freight wagon, whereby it can be rotated even when the freight wagon 1 is at the loading dock or other similar obstacle covering the area of the side beam 12. In the event that the freight wagon is not at the loading dock, the drive means 3 in this embodiment can also be connected directly to the drive shaft 5. In the embodiment of the invention where the drive means 3 is located from the side 10 of the carriage obliquely outwards and upwards, the driving means being located in such a position and position that it can be operated even when the railway carriage is at the loading platform. In order to obtain the direction of vibration on the drive shaft, it must be connected to the drive shaft 5 by a gearbox or similar mechanism.

A conversion mechanism 4 is connected to the drive shaft 5, by means of which the rotational movement of the drive shaft is converted into the pulling or pushing movement of the drive rods 6 depending on the respective position of the roof parts and the direction of rotation of the drive shaft. The drive rods 6 are also generally transverse to the carriage and are connected at their ends remote from the conversion mechanism 4 by means of hinges or joints 28 to levers 7 which are at least one of the two shafts at least one of the shafts. towards the roof part 2, whereby the rotation of the drive shaft causes the drive rods 6 to be filled in the filling movement T outwards or in the traction movement V inwards in the said way, or ri. This pivoting movement of the pivot shafts 8 raises the cover parts to the movement position or lowers them to the closed position in a manner not known per se in a manner not known in the figures.

This arrangement thus means that the railway carriage 1 always has one transfer mechanism 27 for each roof part 2 to be moved to the movement position, and this transmission mechanism 15 thus comprises on both sides of the carriage in which a carriage 1 with a center console and two cover parts 20 2 movable to the movement position and the closing position is described, there are thus two transfer mechanisms 27.

In the embodiment of FIG. The pressure axis 9 of the mating gear 16 is typically perpendicular to the drive shaft 5 and thus longitudinal to the carriage. There are bearing or articulation points 17a and 17b on the surface of the counter-tooth hydrate ul-30 in the vicinity of the test gear, which is approximately transverse to the carriage, and in the embodiment of the figure there are two opposite to each other. These bearing points 17a and 17b are at a radius R from the axis 9 of the counter-rotating gear rotor-35, so that the rotation of the gear to effect the filling of the drive rods 6 or the traction V to turn the pivot shaft 8. These bearing points 17a and 17b can be arranged on the circumference of the counter-toothed hydrator, for example, so that in a certain operating position they are located in the same horizontal plane and the drive rods 6 are directly outside the levers 7. This corresponds to out to its outer position.

5 When the drive shaft 5 is rotated so much that the counter-tooth gear 16 rotates about 180 ° in the embodiment of Fig. 2, the rotating bearing points 17a, 17b again at the upper and lower sides at approximately 6ths intersect at approximately horizontal points. across the transverse surface of the tin gear carriage to the levers 7. In this case, the levers 7 are turned inwards to their outer position. By forming the bearing points 17a and 17b on the circumference of the mating gear 16 at a suitable distance R, the pushing or pulling movement of the drive rods of the desired size is obtained. Depending on the location of the conversion mechanism 4 and the location of the levers 7, joints or the like can also be used instead of the bearings 17a and 17b. The levers 7 and the drive rods 6 are connected to bearings or joints 28. Of course, instead of the screw-thread portion 15, 20 gears can also be used, thus forming a conventional gear gear, but the use of space is generally more advantageous than a screw screw.

Figures 3 and 4 illustrate another embodiment of the conversion mechanism 4 according to the invention, in which the screw 14 of the conversion mechanism 4 and its counterpart 13 are formed by screw coils 18 and 19. It first has a drive shaft 5 connected by a transmission 20, such as a chain drive 1. to the transverse first helical part 18, whereby the rotation of the drive shaft is also rotated by this helical part 18. This first helical part 18 is also connected. the second screw coil part 19 in this case such that the first screw coil part is a male screw and the second screw coil part 19 is a female screw. This second screw helix portion 19 is fixed to the body of the carriage 1 in a non-rotating manner so that it cannot rotate while rotating the first screw helix portion 18, but moves along it during rotation in the directions M1 due to screw transmission. This unsupportability of the pyo- 7 9266b is preferably provided by an axis 22 parallel to the longitudinal line 1 of the carriage, around which this sleeve-like second screw coil part 19 is allowed to tilt. The rotary mat can also be implemented in the cross-sectional shape of the second screw coil part. As an extension of this second screw helix part 19 away from the first screw helix part 18, there is at least one drive rod 26 connected to one lever 7 at a hinge point 28 remote from its pivot shaft 8. In addition, the hub 7 is connected by an auxiliary drive rod 23 to a pivot shaft 8 on the other side of the carriage via a lever 7 therein. If tåsså toteu-dosage form lisåkåyttotangon 23 decided from the kååntdakseleihin 8 KYT keviå levers merkitåån reference numerals 7a and 7b are 15 face to each other in such a way and working example ensimmåinen lever 7a is located kååntSakselista 8 to bottom and the second lever 7b kååntoakselista one side of the carriage 8 ylospåin to kååntoakselit 8 on different sides of the carriage, the movement M2 of the additional drive rod 23 makes it mirror-like with respect to the center line of the carriage length-20. In other words, if one pivot axis rotates in a certain situation on the day of the day, the other pivot axis rotates counterclockwise and vice versa. Thus, in this construction, the rotation of the first helical part 18 causes the second helical part 19 and its extension 26 to rotate along the first helical part, whereby the pivot shaft 8 on one side of the carriage rotates on the side of the carriage 8 on the second drive shaft.

The structure consisting of the first and second helical parts 18 and 19 described above is shown in more detail in Fig. 4. The first helical part 18 is permanently supported or mounted by a guide 29 on the frame 30 of the railway carriage 1.

A slot piece 31, 35 is also attached to the carriage body 30, in the slots 32 of which the ends of the shaft 22 are located. The ends of the shaft 22 thus allow the extension 26 of the second helical part to tilt around the longitudinal line L of the carriage, which is the same as the direction of the shaft 22, and the second helical part 19 and 92665 8 to move its extension 32 along the slot 32. In the structure of Fig. 4, the screw coil part 19 and its extension 26 are rigidly connected to each other by the intermediate part 33.

5

The embodiment of Figure 3 can also be modified in such a way that the primary screw coil part consists of a part of the drive shaft 5 to which the second screw coil part 19 is connected in the same way as described above. It is also conceivable to have a structure in which there is no additional drive rod 23, but for example two second screw coil parts 19 of the type shown are connected to the first screw coil part 18 of the type shown in Fig. 3, which are extended by drive rods 26 in this case. there are two pieces, and the first screw helix part 18 of the container must be approximately in the middle of the width of the carriage. This last described embodiment can be further modified such that the first screw helix part 18 consists of one or two screw helix parts 20 belonging to the drive rod 5, to which two pieces of second screw helix parts are connected. 19 or its extension 26 is, of course, coupled to the carriage run-25 to be tilted about the longitudinal axis of the carriage, but non-rotatably about its axis lines 21, as described above. The second screw coil part is sleeve-like or, as shown in Fig. 3, includes only the sides to which the drive rod 26 is connected to allow a central angle change of the screw coil parts. The second screw coil part of My6s may be male threaded and the first screw coil part may be female threaded.

It is clear that the invention can be modified within the scope of the appended claims. Instead of the screw portions and gears described in the illustrated embodiments, other types of screw or gear hydrate solutions, such as a conical gears or the like, can be used. Likewise, the drive device 3 can be located 92665 9 on the side 10 of the carriage in places other than those shown in the figures and described above. Similarly, there may be a different number of mechanisms for each transfer margin.

5

Claims (9)

92665 10 A roof transfer mechanism in a covered railway carriage (1) having roof parts (2) connected to each other and / or to the carriage body in the closed position, at least one of which is movable by the transfer mechanism 5a (27) from the closed position to the movement position and back. in the longitudinal direction (L) on the cover part in the closed position, this transfer mechanism (27) comprising at least one drive means (3) which, via the drive (10) and the conversion mechanism (4) connected thereto, drives the drive rods (6), or the like via at least one pivot shaft (8) arranged on each side of the carriage for said displaceability of the roof part, characterized in that the drive means (3) is known to be fixed to the side (10) of the railway carriage (1). 12) and fitted with a drive axle (5) extending in the transverse direction of the wagon to be a mechanism (4) including a screw (14) or gear member or the like and its counterpart (13) for converting the rotational movement of the drive shaft 20 (5) into a transverse push or pull movement (T or V) of the drive rods (6, 26, 23); M1, M2) for turning the pivot shaft (8) via said levers (7) or the like. Roof transfer mechanism according to Claim 1, characterized in that the transverse drive shaft (5) of the carriage for obtaining the screw and counter-members (14, 13) of the conversion mechanism (4) comprises a screw helix part (15) or a gear and adapted therefrom. a functioning counter-gear 30 (16), the rotation shaft (9) of which is perpendicular to the drive shaft (5), and that the circumference of this counter-gear has bearing or articulation points (17a, 17b) to which the drive rods (6) are articulated. A cover transfer mechanism according to claim 2, characterized in that said bearing or articulation points (17a, 17b) are two on the circumference of each counter-toothed hydride (16) so that they are located opposite each other at a distance (92) of such a radius (R) 9) that the rotation of the counter-gear wheel causes a predetermined push or pull (T or V) of the drive rods (6) to rotate the pivot shaft (8). 5 Roof transfer mechanism according to Claim 1, characterized in that in order to obtain the screw and counter-members (14, 13) of the conversion mechanism (4) from the transverse drive shaft (5) of the carriage, at least one carriage drive (20) is connected to it. (1) a first helical portion (18) extending transversely, the second helical portion (19) being articulated to the carriage body about its axis line (21) in a non-rotary manner or second helical portions, respectively, wherein the first and second helical portions (18) is operatively interposed to provide a movement (M1) in the direction of the axis (21) of the second helical part when rotating the first helical part and that at least one drive rod (26) is an extension of the second helical part (19). 20 A cover transfer mechanism according to claim 4, characterized in that the first screw helix part (18) is a male threaded rod and the second screw helix part (19) is a suitable female threaded sleeve or the like, the extension (26) of which is articulated to the carriage body (30). - (1) tilt around the axis (22) parallel to the longitudinal axis (L). Roof transfer mechanism according to Claim 4 or 5, characterized in that one conversion mechanism (4) has two screw coil parts (19) and, as extensions *, drive rods (26) or alternatively a second screw coil part (19) and an extension drive rod (26) thereof. ) are one in each conversion mechanism (4) while the pivot shafts (8) on the two sides (10) of the carriage are connected to each other by their pivot levers (7) by an additional drive rod (23) for pivoting ). 92665 12 Roof transfer mechanism according to Claim 1, characterized in that the drive means (3) is arranged in a fixed central console (11) in the central region of the length (L) of the carriage (1) and in that the drive shaft (5) is connected directly to the drive means (3). as an extension thereof or alternatively by means of a chain or belt transmission (25) or a similar mechanism above the drive shaft at a distance therefrom to obtain the drive means at the desired height (H). Roof transfer mechanism according to Claim 1, characterized in that the drive means (3) is arranged in the region of the side beam (12) of the carriage (1) and in that the rotation axis of the drive means points the carriage obliquely upwards and is connected to the drive shaft (5). (3) to make the operating position appropriate. Roof transfer mechanism according to one of the preceding claims, characterized in that it always comprises one transfer mechanism (27) in the railway carriage (1) for each said roof part (2) to be moved to the movement position.