WO1994022703A1

WO1994022703A1 - Braking system for goods wagons

Info

Publication number: WO1994022703A1
Application number: PCT/DE1994/000292
Authority: WO
Inventors: Ottomar Schmidt; Gerhard Umbach; Axel Lenz; Grigori Danilowitsch Kotschmala
Original assignee: Vtg Vereinigte Tanklager Und Transportmittel Gmbh
Priority date: 1993-04-06
Filing date: 1994-03-17
Publication date: 1994-10-13
Also published as: FR2703646A1; FR2703646B1; CZ256094A3; RU2106992C1; BG62321B1; SK130994A3; DE4311362C2; SK283157B6; PL173389B1; DE4311362A1; RU94046355A; BG99259A; CZ288385B6; PL305798A1; RO115034B1

Abstract

An adaptable braking system for goods wagons, in particular for four-axle tank wagons used in transfrontier traffic, should be suitable for two different braking pressures and leverages. For that purpose, a control valve (41, 51) with auxiliary air reservoirs (42, 52) is associated to the pneumatic parts of each braking system. The control valves of both braking systems, which may be shut off from the main air pipe, as well as the auxiliary air reservoirs associated therewith, may be alternately connected to the braking cylinder (1) in the manner of a three-way cock. In the mechanical part of the braking systems, drawbars (21) may be mounted on alternative joints (E, F) between the horizontal compensating levers (8, 9) for adapting the ratios of transmission and leverages to the corresponding braking system. The main brake drawbars may be articulated on longitudinally and vertically offset bearing points of the braking arrangements of normal and wide gauge bogies by means of slides arranged on both parts of the main brake drawbar.

Description

Braking system for freight cars

The invention relates to a braking system for freight cars that are used in cross-border traffic and in which the braking system is to be adapted to two different operating pressures and lever ratios.

While European railways use operating systems for braking railway vehicles according to the regulations of the UIC (Union Internationale des Chemins de Fer), a different operating system is required in the CIS countries. The differences are e.g. in power and lever ratios and in operating pressures. In the UlC system, the control operating pressure in the main air line is 5.0 bar, while in the GUS system, the pressure is usually 5.5 bar. There are also fundamental differences when releasing the brakes. Braking systems that are located on the underframes of freight cars and that can be used for one as well as for the other operating systems with different operating pressures, lever ratios and bogies are not known.

It is therefore an object of the present invention to design the parts of the braking devices located on the undercarriage of freight wagons so that they can be used in various operating systems with e.g. different operating pressures, lever ratios and bogies can be used. In particular, it should be provided that the braking devices can be used both in the UlC system or analog operating systems and with the brake-specific features of the GUS system or analog operating systems.

REPLACEMENT LEAF This object is achieved by the features specified in claim 1. The subclaims relate to preferred further developments.

In conventional braking devices, the pneumatic part consists of a main air line running under the entire length of the frame, a control valve with an auxiliary air tank, various

Actuators and the brake cylinder to which the mechanical parts of the brake device connect. Lowering the operating pressure activates the brake. The mechanical part consists of a central brake linkage which comprises two horizontal compensating levers which are articulated on the one hand on the brake cylinder or the piston rod and on the other hand are connected to the main brake drawbars which lead to further braking devices in the bogies. At least one tie rod is located between the two compensating levers, about the end points of which the compensating levers rotate when the piston rod is moved. There are also facilities that change the load regime, i.e. change the braking behavior, depending on whether the freight wagon is full or empty.

Devices of this type are described in DE 610 803 or Knorr-Bremse GmbH, Brake Technology Works for Railway Vehicles, edition 1951, page 8 and are used in the UlC system. They are not used to compensate for differences in different operating systems.

According to the invention it is provided in the pneumatic part that for each of the two control operating pressures and other peculiarities of the mode of operation and operation of the brakes, a control valve with an auxiliary air tank is provided, the control valves used being those for the UIC or GUS system or analog Systems are approved. One is in the lines from the control valves to the brake cylinder

Valve arrangement with the function of a three-way valve, in the simplest case even only a three-way valve, so that the brake cylinder is operated only with one of the two control valves selected. The three-way valve or its actuation is preferably locked or closed, so that its changeover to the other control valve cannot take place unintentionally.

In the mechanical part, the effective position of the tie rod between the horizontal compensating levers is changed according to the invention. While in the GUS system the load change takes place pneumatically, depending on the loading condition, through an adjustment on the control valve, there are versions with UlC systems with pneumatic influence through adjustment on the control valve as well as with mechanical influence through a change in the effectiveness of the tie rods in the Center brake linkage. The solution according to the invention is suitable for both versions. It provides that in addition to the tie rods according to the UlC system, another tie rod is arranged between the compensating levers, the articulation of which is selected in accordance with the operation on the CIS railway. The articulation points of this towing bar are relatively close to the brake cylinder on the leveling levers. It is therefore advisable to carry them out in a bent or kinked form so that they do not touch the brake cylinder. This load tie rod is therefore preferably connected to the neighboring tie rod of the UlC system by cross connections to form a structural unit, this unit being supported and guided in the horizontal plane between the compensating levers. By alternately clearing certain bolt connections on the tie rods, the desired braking force transmission is achieved in the respective system. The bolts are released by removing them from the tie rod that is not active. The main brake pull rod is articulated to the different position of the trigger points of the brake lever system of bogie types by means of a length and height adjustable sliding piece, which can also be designed as a fixed intermediate piece. Further preferred details emerge from the subclaims and from the description of the accompanying drawings. The drawings are only non-scale, schematic representations in a simplified form.

Show it

Fig. 1 shows the pneumatic and the mechanical part of a brake system in which a load changeover takes place on the control valves

2 shows a center brake linkage for a brake system, the load changeover being carried out mechanically for the UIC brake system. The bolt connection of the load rod for the power transmission in the CIS brake system is cleared so that the brake works in the UlC system, in the given case in the "empty" load regime in the release position.

Fig. 3 as Fig. 2, but the center brake linkage is shown in the braking position at the load level "empty", wherein the holes F 'and E' on the tie rod 31 do not match the holes F and E of the compensating lever 8, 9. Fig. 4 is a center brake linkage for a brake system, each having a bolt connection of the idle rod and the load rod for power transmission in the UIC brake system are cleared, so that the brakes work in the CIS brake system, in the given case in the release position.

Figure 1 shows, on the base frame, not shown, is the center brake linkage, which comprises the brake cylinder 1 with the piston rod 2 and the horizontal compensating levers 8, 9 as well as load tie rods 21, 22 extending between them. The fixed point compensating lever 9 is on the one hand attached to a fixed pivot point B on the brake cylinder 1 and its pivot point D at its other end is connected to the main brake pull rod 7, which leads to a bogie, not shown. The cylinder compensation lever 8 is connected to the piston rod 2 at the articulation point A and to another main brake drawbar 7 at the articulation point C. A tow bar 22 is attached to the articulation points G and H of the two compensating levers 8, 9. When compressed air is fed into the brake cylinder 1, its piston rod 2 extends and this leads to the compensating levers 8, 9 pivoting about points G and H and the main brake pull rods 7 being pulled together with points C and D, as a result of which the braking effect on the wheels is exercised.

According to the invention, it is now provided to arrange a further tow bar 21 at articulation points E and F between the compensating levers 8 and 9.

In the braking system of the GUS railways, the articulation points E and H are proportionate due to the differences in the gear ratios in the bogies and the use of plastic brake blocks close to the brake cylinder 1 or at the articulation points A and B. For this reason, the drawbar 21 is also curved or kinked so that it does not touch the brake cylinder. The pull rod 22, which is effective for the UIC brake, is located at a greater distance from the brake cylinder 1. The system with the higher operating pressure in the main air line, for example, is the system of the GUS railways than the UlC system with the lower pressure. System.

Depending on the system, either the load tie rod 21 at the articulation points E and F or the load drawbar 22 at the articulation points G and H is fastened to the horizontal compensating levers 8, 9 by means of articulated pivot pins drawn as black dots.

The articulated eyes of the non-engaging truck are shown as white circles. They can be moved freely on the compensating levers 8, 9 relative to the articulation points E and F or G and H, as is shown, for example, in FIG. 3.

It is advantageous to connect the drawbars 21 and 22 by cross connections 23 so that they are designed as a structural unit which extends in the horizontal plane between the compensating levers and which is supported or guided in some other suitable manner without the mobility is affected.

The two main brake pull rods 7 are connected by a push rod 10, the control bracket of which is displaceable on one part of the rod 7. The rod 7 also has a brake linkage adjuster 4. At the two free ends of the rods 7 there are sliding pieces 5,

SPARE BLADE which are adjustable in length and height on the main brake cable, and can be locked in such a way that they can be connected to the other parts of the brake system in the bogies at different positions of the articulation points.

The pneumatic part shown in Fig. 1 has a main air line 40, which has at its ends stopcocks and connecting parts to adjacent cars. A control valve 41, of the type customary for UlC systems, is connected to the main air line 40. An auxiliary air container 42 is assigned to it. The connection between the main air line 40 and the control valve 41 can be interrupted by a shut-off valve, of which only the actuation lever 43 is shown. A load change for a different braking behavior when the car is empty and loaded can be set on the control valve 41 via the actuating lever 44. The actuation for the type of braking freight train or passenger train on the control valve 41 is made via a further actuating lever 59. Another line branches off from the main air line 40 via a shut-off valve 53 to a further control valve 51, which is common and approved for the GUS system, for example. An auxiliary air tank 52 is also assigned to the control valve 51. The load change on the control valve 51 can also be changed pneumatically by means of the actuation 54. The actuation 57 is used to set the type of braking, for example in the GUS system for flat and mountain areas on the control valve 51.

Brake air lines 45 and 55 run from the control valves 41 and 51 to a three-way valve 50, which can be changed over by the actuation 49 and thereby connects the brake cylinder 1 either to the control valve 41 or to the control valve 51. The three-way valve 50 or another valve device with this function must be secured so that an unintentional and impermissible change cannot take place; For example, so that the change from one brake system to the other is only possible when changing the bogie.

2 and 3, center brake linkages are shown in various positions, in which the load change can be carried out mechanically by means of the actuation 60 for UIC systems or analogs. In this case, the tie rods 32 and 33 are available for the UlC system, and the further tie rod 31 is arranged for adaptation to the GUS system. Here, too, the towing rods 31 and 32 are connected to a structural unit 35 by cross connections 34. In operation with the GUS system, shown in FIG. 4, the load-rod 31 is connected to the compensating levers 8 and 9 by bolts inserted at the articulation points E and F. The hinge pins at the hinge points G and H are removed in this case, i.e. there is a bolt change between the points GH / EF. This bolt change can alternatively take place between the points GM / EF.

Fig. 2 shows the center brake linkage in the load level "empty" of the mechanically adjustable system, such as the UlC system, in the release position. At the articulation point H, a claw 36 is arranged around the articulation bolt located in an elongated hole at one end of the pull rod 32, on which there is a butt edge 37 which can abut a stop 38. A slight play 39 between the abutting edge and the stop is expedient for quickly overcoming the total play in the brake linkage when braking is initiated. Claw 36 and stop 38 are in a load change box, not shown. To switch to the load level, the claw 36 is released in the direction of the arrow indicated. In Fig. 2 also the hinge eyes E and F are not attached to the compensating levers 8 and 9, ie this representation corresponds to the operation with the UIC brake system or an analog with mechanical load changeover.

Fig. 3 shows the braking position for the representation in Fig. 2. It is shown on an unjust scale that the holes E ', F' for the bolt receptacle on the tie rod 31 a differentiated position to the holes E, F on the horizontal compensating levers 8th and take 9.

The respective arrangement of the articulation points F-E, G-H and M-N on the horizontal balancing levers can be calculated according to the overall lever ratios and the necessary power transmission for each rail system.

By using fewer, but in principle conventional parts, the present invention creates a braking system that can be used with relatively few changes in different operating systems of different tracks.

Claims

1.Brake system for freight cars using control valve, auxiliary air tank, brake cylinder, center brake linkage with tie rods and horizontal compensating levers, main brake tie rods with linkage adjuster and devices for load changeover as well as further operations of the brake on the base frame of the freight car, characterized in that the for mutual adaptation to two different operating systems pneumatic part of the brake systems, a control valve (41, 51) with auxiliary air tanks (42, 52) is assigned, the control valves (41, 51) of the two brake systems, which can be shut off from the main air line, and the auxiliary air tanks (42, 52) assigned to them, alternately in the manner of a three-way valve (50) can be connected to the brake cylinder (1), and an additional tie rod (21, 31) is arranged between the horizontal compensating levers (8, 9) in the mechanical part for changing over the brake systems, so that at alternative articulation points (E, F or C- , H, M, N) of the compensating lever (8, 9), tie rods (21, 22, 31, 32, 33) can be attached to adapt the power and lever ratios to the respective brake system and the linkage of the main brake cable to length and height differentially located trigger points of the brake devices of the bogies for the respective brake system is realized by means of a sliding piece (5) on the two parts of the main brake cable rods (7). Brake system according to claim 1 with pneumatic load changeover, characterized by articulation points (E, F) on the horizontal compensating levers (8, 9) near the brake cylinder (1) and a load-pull rod (21) which can be used between them for the brake system of the GUS railways or analog brake systems and by further articulation points (G, H) for a towbar (22) at a greater distance from the brake cylinder (1), only one of the towbars (21, 22) being in engagement.

Brake system according to claim 2, characterized in that the tie rods (21, 22) form a structural unit (24) by means of cross-connections (23), which in the horizontal plane between the compensating levers

(8, 9) is movable and guided.

Brake system according to claim 1 for a mechanical load change in the brake system of the UIC or analog system and pneumatic load change in the brake system of the GUS railways, characterized in that for the operation with the UIC brake system a first pull rod (32) at articulation points (G, H) for the unloaded state and at a greater distance from the brake cylinder (1) at the articulation points (M, N) there is a second pull rod (33) for the loaded state and can be activated and an additional one for operation with the system of the CIS railways Drawbar (31) is provided at articulation points (E ^# , F ') near the brake cylinder (1) that the tie rod (31) and the tie rod (32) form a structural unit (35) which is movable and guided in the horizontal plane between the compensating levers (8, 9) and only one of the tie rods (31, 32) Bolt is firmly connected to the horizontal leveling levers (8, 9).

Brake system according to claim 4, characterized in that the structural unit (35) between the tie rods (31, 32) is created by means of cross connections (34).

Brake system according to one of claims 1 to 4, characterized in that the tie rod connection to be used for the respective brake system can be produced by moving articulation bolts between the articulation points (E, F and G, H or EF and GM).

Brake system according to one of claims 1 to 6, characterized in that the compensating lever (8, 9) begins at the outer ends of the at the articulation points (C, D)

Main brake pull rods (7) sliding pieces (5) for the

Length and height adjustable fixed intermediate pieces are arranged, on which the differently designed braking devices of the bogies can be articulated. Brake system according to claim 1, characterized in that the diverter (49) for the three-way valve (50) for

Change the brake system and / or the three-way valve

(50) itself can be mechanically locked securely in the selected position, the brake shut-off valves (44, 53) of the control valves (41,

51) can also be locked in the switched-off position.