SE437637B - AUTOMATIC DOUBLE-OPERATING ADJUSTMENT FOR BRAKE MECHANISM - Google Patents

Description

7804521-8 The lifting ring and an axial bearing, on the brake ball side, a stop arranged on the rod part of the brake cylinder side at a certain distance, and an accumulator spring clamped between the lifting ring and the sleeve end located on the brake cylinder side. An adjusting device of this type is previously known from German Patent Specification No. 944 858. When using such adjusting devices, it has been found that due to oscillations and shocks, unintentional adjustments can take place.

In order to eliminate this disadvantage, according to German Patent Specification No. 1,530,260, it has been proposed to arrange in the coupling, between the draw sleeve and the lifting ring, a running sleeve which axially displaceably engages in the lifting ring by means of an axially directed arm. With the aid of the coupling spring, the running sleeve can be clamped in a rotationally fixed manner between the end of the brake cylinder side of the traction sleeve and the stop cooperating with the lifting ring via the axial bearing. This made it possible to utilize the relatively high differential force between the coupling spring and the accumulator spring as closing force for couplings which in the off state of the brake frictionally couple the housing to the bar part of the brake cylinder side, thereby increasing the resistance which must be overcome for rotation of the housing. . For manual adjustment of the mechanism, the housing must be rotatable by manual means, and the usable rotational resistance is thereby reduced.

The device according to German Patent Specification No. 1,530,260, however, has the disadvantage that in the adjusting device there must be an additional coupling, namely a coupling between the running sleeve and the lifting ring in cooperation with the axially directed arm, whereby the complexity increases. Furthermore, the arm of the running sleeve must be axially displaceably mounted in a recess in the lifting ring, something that is not possible without play. As the running sleeve is kept pivotable as a result of this play, the lifting ring will therefore be rotatable to a certain extent, and this rotatability is also transmitted via the accumulator spring to the housing.

The housing thus forms a mass connected via the accumulator spring elastically to the lifting ring provided with a pivot. Especially when the adjusting device is vibration-loaded with the natural frequency of the mentioned parts, torsional oscillations can thus be generated which give rise to undesired adjustments.

The object of the invention is to design an adjusting device of the type initially indicated in such a way that with a slight increase in the complexity, without any further connection being required, as in the case of the device according to German Patent Specification No. 1,530,260, an increased protection against - visible adjustment as a result of oscillations or shocks, whereby, however, parts made with swivel play are avoided and thereby, in addition to a reduction of resonant oscillations, a reduction of the wear is also achieved. : This is achieved according to the invention in that on the rod part of the brake cylinder side there is an additional stop, against which the lifting ring abuts directly or indirectly on the brake ball side.

According to a variant of the invention, it is advantageous in this case if the further stop in a manner known per se consists of a locking ring inserted in the rod part, and if furthermore the stop which can be connected to the sliding sleeve has pipe sections surrounding the brake cylinder side bar part and whose end car - where the existing stop on the brake ball side opposite the lifting ring.

The invention is explained in more detail below with the aid of exemplary embodiments shown in the accompanying drawing, in which Fig. 1 shows the location of the adjusting device in a braking device, Fig. 2 shows, in half, on an enlarged scale, and on an enlarged scale, the brake ball side part of an adjusting device. Fig. 3 shows a section corresponding to that in Fig. 2 of the remaining adjusting device on the brake cylinder side and Fig. 4 shows a section through a modified embodiment.

According to Fig. 1, a brake cylinder 1 is arranged in a conventional H-brake mechanism 2 with two brake levers 3 and 4.

The brake lever 3 is articulated connected to an ear 5, which is located at the end of a rod part 6. The rod part 6 belongs to an adjusting device 7 and slidably supports an operating stop 8, which is 51%? ä '__ i 1.51; 7eo4s21-s via a rod 9, together with a brake rod leading to a ball brake (not shown), is articulated connected to the second brake lever 4. The song part 6 leads into a housing l2 on adjusting device ~ en 7, and from the other end of this housing protrudes a rod part 13, which leads to a conventional ball brake device 15 for a vehicle wheel 14.

Based on the principle drawing in Fig. 1, the two sides of the adjusting device 7 are hereinafter referred to as the "brake cylinder side" and the "brake ball side".

According to Figs. 2 and 3, the housing 12 of the adjusting device 7 is elongate and tubular and is covered at the end of the egg cylinder side by a lid 16 and is opposite / closed by a lid 17. The rod part 6 of the brake cylinder side is formed relative to the housing 12 as a thinner tube and extends into the housing 12. The brake part side bar part 13 has a common axis line with the bar part 6 and extends from the other side into the housing 12 and ends inside the bar part 6 with a sliding guide 18. The brake cylinder side bar part 6 ends in the housing 12 with a screwed-on shoulder 19 .

The brake part 13 of the brake pad side is provided with a non-self-inhibiting thread 22, on which a displacement nut 23 is screwed and, displaced in the direction of the brake cylinder side therefrom, a lock nut 24. The displacement nut 23 forms on the one hand together with the inside of the cover 17 a preferably toothed coupling a - a and is loaded on the other hand via an axial bearing 25 by a spring 26, which is caught on the brake cylinder side by a tube-like draw anchor 27. The draw anchor 27 rests on the brake ball side against an inner wall of the housing 12 locking ring 28. On the side of the brake cylinder, the drawbar anchor 27 abuts against the end surface of the locking nut 24.

As a variant of the exemplary embodiment shown, it is also possible to design the flange part included in the coupling a - a on the displacement nut 23 separately and separately movable, but nevertheless inextricably connected to the displacement nut, as is known, for example, from German Patent Specification No. 941,914.

The locking nut 24 has near its outer periphery on both sides conical coupling surfaces and is gripped by a longitudinally displaceable and rotatably controlled pull sleeve 29. On the brake ball side, the pull sleeve 29 has a radially inwardly directed flange 30, which together with the lock nut 24 forms a coupling b - b. On the brake cylinder side of the locking nut 24 there is in the pull sleeve 29 an axially displaceable sliding sleeve 31, which, however, is non-rotatable by means of a pin 33 engaging in a slot 32 in the sliding sleeve.

The end of the brake pad side of the sliding sleeve 31 together with the coupling surface of the brake cylinder side on the lock nut 24 forms a coupling c - c. At the other end the sliding sleeve 31 ends with a radially inwardly directed flange, the restriction of which on the brake pad side together with the brake cylinder side - d. The coupling surfaces in the coupling d - d are bevelled and form a conical coupling. On the brake ball side, the shoulder 19 also has a conical surface, on which a coupling ring 34 is mounted. A spring 36 supporting on the brake ball side via an axial bearing 35 against the lock nut 24 presses the coupling ring 34 against the shoulder 19. Radially outwards the coupling ring 34 has a nose with which it engages in the slot 32 in the sliding sleeve 31 and is thereby non-rotatable, but axial slidably guided in the sliding sleeve 31. Between the end surface of the brake cylinder side of the sliding sleeve 31 and a flange part 37 screwed into the draw sleeve 39 in its end facing the brake cylinder, a coupling spring 38 is clamped, which loads the sliding sleeve 31 in the coupling direction.

The end of the brake cylinder side on the flange part 37 forms together with the conical end surface of a lifting ring 39 facing the brake ball side a coupling e - e. The lifting ring 39 is rotatably and axially displaceably mounted on the rod part 6 with small axial play between two abutment members arranged in the rod part 6. locking rings 40 and 41, an axial bearing 42 being arranged between the locking ring 40 of the brake pad side and the lifting ring 39. The flange part 37 is located at a certain distance from the locking ring 40 and cannot come into engagement with the locking ring 40.

The end surface of the brake cylinder side on the lifting ring 39 is also conically shaped, and against this surface the end of the brake ball side of an accumulator spring 43 abuts, which is weaker than the copper spring 38, but in relation to this is nevertheless relatively long. . The end of the brake cylinder side of the accumulator spring 43 abuts against a conically shaped counter surface 44 on the cover 16 of the brake cylinder side.

The operating stop 8 is located at a distance A from the outside of the brake cylinder side of the cover 16, the distance A corresponding to the starting stroke of the ball brake device 15.

A sealing ring 45 arranged in the lid 16 seals the rod part 6 in the lid 16.

The opposite cover 17 is connected via a sealing ring 46, which allows certain angular deviations. with a pipe section 47, which surrounds and protects at least the threaded section on the rod part 13 of the brake ball side 13. The end of the displacement nut 23 of the displacement nut 23 is provided with a cylindrical shoulder 48 which engages with a small play in a corresponding recess in the cover 17. It should be noted that the spring 26 is weaker than the accumulator spring 43, and that the spring 36 is in turn weaker than the spring 26. In the rest position, when the brake is switched off and the correct contact stroke for the ball brake device 15, all parts of the adjusting device 7 assume the position shown in Figs. 2 and 3. The couplings a - a, c - c, d - d and e - e are engaged, while the coupling b - b is out of engagement. The force flow from the coupling spring 38 runs in the brake ball direction via the sliding sleeve 31, the coupling d - d, the shoulder 19 and via the rod part 6 back to the locking ring 41 and from this further over the lifting ring 39, the coupling e - e and the flange part 37 to the coupling spring 38 The force from the accumulator spring 43 runs in the direction of the brake ball via the lifting ring 39, which via the stronger coupling spring 38 is kept pushed away from the locking ring 40, via the coupling e - e, the flange part 37, via the coupling spring 38 to the sliding sleeve 31 and from this again via the coupling c - c, the locking nut 24, the closing part 13, the displacement nut 23 and the coupling a - a to the lid 17 and from this via the housing 12 back to the lid 16 and the accumulator spring 43. The force flow from the spring 26 is closed via the draw anchor 27 , the housing 12, the cover 17 and the coupling a - a and the displacement nut 23. The force from the spring 36, finally, presses the coupling ring 34 against the shoulder 19, then runs via the coupling d - d and the sliding sleeve 31 and the coupling c - c, which against the substantially greater force from the accumulator spring 43 loads it in the opening direction, and the locking nut 24 and the axial bearing 35 back to the spring 36.

The springs 26 and 36 are substantially weaker than the clutch spring 38 and the accumulator spring 43, which, for example, have a spring force of 2500 N and 1500 N, respectively. Under negligence of the slight action of the springs 26 and 36, it is thereby obtained that each of the clutches a a and c - c are engaged with the force from the accumulator spring 43, amounting to, for example, 1500 N, that the coupling d - d is kept engaged by the difference between the forces of the coupling spring 38 and the accumulator spring 43, thus for example 1000 N, and that the coupling e - e is kept in engagement with the sum of the forces from the coupling spring 38, thus with for example 2500 H.

For adjusting the switch-off gap of the ball brake device 15, which e.g. may be necessary when replacing worn brake pads, the housing 12 is turned manually, possibly with the help of a suitable tool. Via the coupling a - a the displacement nut 23 and via the accumulator spring 43 present in frictional engagement with the cover 16 and abutting the lifting ring 39, the lifting ring 39 and the pull sleeve 29 and via the coupling c - c the lock nut 24 will be brought along, so that both nuts 23 and 24 is rotated on the rod part 13 in correspondence with the rotation of the housing 12. In this rotation the frictional engagement in the coupling d - d, the friction from the coupling ring 39 towards the shoulder 19, and a certain friction between the lifting ring 39 and the locking ring 41 and the possible the co-rotating locking ring 41 against the rod part 6 is overcome.

It is essential that the housing 12 in the switched-off position does not have any free pivot gap relative to the rod part 6, but p via the coupling d - d and the locking ring 41 is pivot-free and force-closing coupled. Therefore, no increased wear can occur as a result of impacts against any steering parts, or oscillations occur as a result of playful rotational controls, as the adjusting device is subjected to shocks and vibrations during driving of the vehicle during the travel of the vehicle.

It is essential that the small axial clearance of the lifting ring 39 and the axial bearing 42 between the two locking rings 40 and 41 can be maintained during manufacture without tight tolerances having to be maintained. In this case, it is also important that the distance from the coupling surface located on the shoulder 19 in the coupling d - d to the locking rings 40 and 41 can be maintained with dimensional accuracy without special measures.

The function of the adjusting device 7 when braking with a normal, too small or too large abutment stroke of the ball brake device 15 corresponds to the mode of operation of known, similar devices, for example according to German Pat. 944 858 and l 530 260, and it therefore does not need to be described in more detail here. I.

The adjusting device described above can be given a simplified construction according to Fig. 4, in that the shoulder 19a connected to the brake part 6 of the brake cylinder side on the brake cylinder side has a tube-like shoulder 49 which surrounds the lock member 6 and ends with little play before the end of the brake cylinder side on the shoulder 49 thereby takes over the function of the locking ring 40 shown in Fig. 2, which thus disappears in the embodiment according to Fig. 4.

Furthermore, between the lifting ring 39 on the one hand and the accumulator spring 43 and the locking ring 41 on the other hand, there can be a coupling ring, not shown on the rod part 6. The lifting ring 39 then supports via this coupling ring indirectly both against the accumulator spring 43 and against the locking ring 41.

Enea QUAmY

Claims (3)

1. 9 7804521-8 Claims 1. Automatic, double-acting adjusting device (7) for brake mechanism, in particular on rail vehicles, provided with two torsionally held rod parts (6, 13) with a common axle line, one of which (6) is tubular and is articulated connected to a brake mechanism section (brake lever 3) on the brake cylinder side, and the other (13) is provided with a non-self-braking thread and is hingedly connected to a brake mechanism section (ball brake device 15) on the brake ball side, and with both connecting the rod parts (6 and 13) connecting housing (12) accommodating the adjusting means, the adjusting means comprising a displacing nut (23) screwed together with the thread and a locking nut (24) also screwed together with the thread, a locking nut (24) engaging, on the brake ball side therewith coupling (coupling b - b) tension sleeve (29), one in this non-rotatable, axially displaceable controlled, on the brake cylinder side with the lock nut (24) and a stop (shoulder 19) on the brake part (6) of the brake cylinder side sliding sleeve (31), a sliding sleeve (31) in the coupling direction loading, between the sliding sleeve (31) and the draw sleeve (29) clamping spring (38), a clamping spring (38) between the end of the draw sleeve ( 29) and a coupling ring (39) rotatably and axially displaceably mounted on the rod part (6) of the brake cylinder side, a stop (39 -) and an axial bearing (42) arranged on the brake ball side, at a certain distance, at a certain distance the locking ring 40 and the respective shoulder 49) on the bar part (6) of the brake cylinder side, and an accumulator spring (43) clamped between the lifting ring and the housing end located on the brake cylinder side (cover 16), characterized in that on the bar part (6) of the cylinder side there is an additional stop (locking ring 41), against which the lifting ring (39) rests directly or indirectly on ... w-au- ~ 1-I + w 7804521-8 m the brake pad side. Adjusting device according to Claim 1, characterized in that the additional stop in a manner known per se consists of a locking ring (41) inserted in the rod part (6). Adjusting device according to Claim 1 or 2, characterized in that the stop (shoulder 19) which can be connected to the sliding sleeve (31) has a tube section (shoulder 49) which surrounds the rod part (6) of the brake cylinder side, and whose end forms it on the brake pad side opposite the lifting ring (39) existing stop.