Friction shock absorber

Abstract

The present invention relates to the field of transport mechanical engineering. Objectimprove performance and operational reliability of a friction shock absorber. The friction shock absorber (FIG. 2) comprises housing (1), whose walls form orifice (2), and bottom (4) that is in contact with return-and-retaining device (5) contacting a friction assembly that consists of the following elements fitted out with friction surfaces (f1-f10): supporting plate (10), pressure wedge (6), stay wedges (7), and reverse-U-shaped movable plates (9) fitted out with side shelves (14) that cover guide plates (8) and are located on supporting plate (10). Return-and-retaining device (5) is available between the guide plates. Additional return-and-retaining device (11) is available between the pressure wedge and the supporting plate. Recesses for the return-and-retaining device and hard lubricant inserts are available on the guide plates; Movable plates may be partially T-shaped forming side shelves that are located on the supporting plate. Hooks (15, 16) are available on the pressure wedge and stay wedges, located so as to enable a mutual contact during the back stroke of the pressure wedge.

Claims

1. Friction shock absorber that comprises housing (1), whose walls (3) form orifice (2), and bottom (4) that is in contact with return-and-retaining device (5) contacting a friction assembly that consists of the following elements fitted out with friction surfaces (f1-f10): supporting plate (10), pressure wedge (6), stay wedges (7), and movable plates (9) fitted out with side shelves (14) resting against support plate (10), and guide plates (8) with return-and-retaining device (5) between them, wherein an additional return-and-retaining device (11) is available between pressure wedge (6) and supporting plate (10) of the friction assembly.

2. Shock absorber according to claim 1, wherein recesses (13) are available for return-and-retaining device (5) on guide plates (8).

3. Shock absorber according to claim 1, wherein hard lubricant inserts (12) are available on guide plates (8).

4. Shock absorber according to claim 1, wherein movable plates (9) are partially inverted-U-shaped, forming side shelves (14) that cover guide plates (8) and are located on supporting plate (10).

5. Shock absorber according to claim 1, wherein movable plates (9) are partially T-shaped forming side shelves (14) located on supporting plate (10).

6. Shock absorber according to claim 1, wherein hooks (15, 16) are available on pressure wedge (6) and stay wedges (7) located so as to enable a mutual contact during the back stroke of pressure wedge (6).

Description

(1) The invention is further described in detail with reference to the accompanying figures, wherein: FIG. 1 shows a top view of the friction shock absorber's utility model wherein movable plates per FIG. 4 are utilized; FIG. 2 shows integrated frontal section A-A per FIG. 1, wherein on the left-hand side the friction shock absorber is shown in its original position, while on the right-hand side it is demonstrated in its compressed state; FIG. 3 shows the guide plate with recesses for the return-and-retaining device; FIG. 4 shows a general view of the friction shock absorber's movable plate per FIGS. 1 and 2; FIG. 5 shows a top view of the friction shock absorber's utility model wherein movable plates per FIG. 7 are utilized; FIG. 6 shows integrated frontal section B-B per FIG. 5, wherein on the left-hand side the friction shock absorber is shown in its original position, while on the right-hand side it is demonstrated in its compressed state; FIG. 7 shows a general view of the friction shock absorber's movable plate per FIGS. 5 and 6; FIG. 8 shows a general view of the friction shock absorber's pressure wedge.

(2) The friction shock absorber (FIGS. 1, 2, and 5, 6) comprises housing 1 that is symmetrical to main axis O-O (FIG. 2, 6) and has orifice 2 formed by its walls 3, and bottom 4, contacting return-and-retaining device 5 (conventionally shown by crossed straight lines), contacting with its other side the friction assembly (FIGS. 1, 2, and 5, 6) that consists of pressure wedge 6, stay wedges 7, guide plates 8, movable plates 9, and supporting plate 10.

(3) Movable plates 9 are located on supporting plate 10 (shown by dashed lines in FIGS. 2 and 6).

(4) These elements 6-10 of the friction assembly have friction surfaces, wherewith they adjoin each other in pairs:

(5) pressure wedge 6 adjoins one of friction surfaces f2 of stay wedges 7 with its surface f1;

(6) the other friction surface f3 of stay wedges 7 adjoins friction surface f4 of supporting plate 10;

(7) the third side friction surface f5 of stay wedges 7 adjoins friction surface f8 of one of guide plates 8;

(8) friction surface f7 of the other side of guide plates 8 adjoins friction surface f6 of one of the surfaces of movable plates 9;

(9) friction surface f9 of the other side of movable plates 9 adjoins friction surface f10 of walls 3 inside orifice 2 of housing 1;

(10) Additional return-and-retaining device 11 (conventionally shown by cross straight lines) is available between pressure wedge 6 and supporting plate 10 of the friction assembly.

(11) Return-and-retaining device 5 and additional return-and-retaining device 11 may be represented (not shown) by one or several compression springs, or by resilient-elastic elements, a hydraulic or other element.

(12) In order to improve the performance of pairs of friction surfaces f5-f8 and f7-f6 when stay wedges 7 and movable plates 9 travel along guide plates 8, it is useful to install hard lubricant inserts 12 on guide plates 8, either on one side, or on both sides of guide plates 8 facing movable plates 9 and stay wedges 7. Such hard lubricant inserts 12 allow to minimize the probability of the aforementioned friction surfaces clamping together or sticking up to each other, and to secure smooth movement of the friction assembly back to its original position.

(13) To ensure that powerful return-and-retaining device 5 is positioned in a space-saving manner, recesses 13 for the return-and-retaining device are available on the guide plates within housing 1.

(14) Movable plates 9 may have a reverse-U-shaped parts (FIGS. 2 and 4), whose side shelves 14 cover (FIG. 1) guide plates 8 and are located on supporting plate 10.

(15) Movable plates 9 (FIG. 7) may also be partially T-shaped forming side shelves 14 that are located on supporting plate 10.

(16) To prevent the friction shock absorber from jamming, it is useful for pressure wedge 6 to have hooks 15 (FIGS. 2, 6, and 8), and for stay wedges 7 to have hooks 16 (FIG. 2, 6) located so as to enable a mutual contact (right-hand side of FIGS. 2 and 6) during the back stroke of pressure wedge 6 to bring stay wedges 7 into their original position.

(17) The operating principle of the friction shock absorber is based on the fact that return-and-retaining device 5 is compressed, when external force P (right-hand sides of FIG. 2, 6) is applied to pressure wedge 6 at the side of the drawbar (not shown) when the cars collide.

(18) In this case the friction assembly is buried into orifice 2 of housing 1. Pressure wedge 6 brings stay wedges 7 inside housing 1.

(19) At a certain phase of the stroke, the pressure plate (not shown) of the automatic coupling device of the car (not shown) begins pressing on movable plates 9 (right-hand sides of FIG. 2, 6). When exposed to this force, they enter into housing 1 along guide plates 8 and walls 3 experiencing friction.

(20) Further on, due to the inclination to main axis O-O of the friction shock absorber, they move towards this axis on guide plates 8, sliding along them, as well as along friction surfaces f1 of pressure wedge 6 and supporting plate 10.

(21) When external force P is released, additional return-and-retaining device 11 pushes pressure wedge 6 away from stay wedges 7, which pressure wedge uses its hooks 15 to catch hooks 16 of stay wedges 7 helping them to return to their original position. As a result, return-and-retaining device 5 can release in a much easier way, pushing supporting plate 10 back into its original position along with the friction assembly installed therein.

(22) This way, due to the force exerted by additional return-and-retaining device 11 on pressure wedge 6, a part of that force is transmitted to stay wedges 7, which allows to use the force exerted by additional return-and-retaining device 11 to not only disengage the surfaces of pressure wedge 10 and stay wedges 7, but to also disengage stay wedges 7 and guide plates 8.

(23) This helps to improve the friction shock absorber's performance and operational reliability by preventing it from jamming.

REFERENCES

(24) 1. Patent U.S. Pat. No. 7540387, IPC F16F7/08, B61G9/00, priority date Aug. 10, 2011, publication date Oct. 28, 2014.

(25) 2. Patent RU2338100, IPC F16F7/08, B61F5/08, priority date Apr. 18, 2006, publication date Nov. 10, 2008/prior art/.

LIST of reference designations and elements to which they refer

(26) TABLE-US-00001 No. ELEMENT 1 housing 2 orifice 3 housing 1 wall 4 housing 1 bottom 5 return-and-retaining device 5 6 pressure wedge 7 stay wedge 8 guide plate 9 movable plate 10 supporting plate 11 additional return-and-retaining device 12 hard lubricant insert 13 recess for guide plate 8 14 side shelf in movable plate 9 15 hook in pressure wedge 6 16 hook in stay wedge 7 A-A designation of the integrated frontal section per FIG. 1 B-B designation of the integrated frontal section per FIG. 5 f1 friction surface of pressure wedge 6 f2, f3, and friction surfaces of stay wedges 7 f5 f4 friction surface of supporting plate 10 f6 and f9 friction surfaces of movable plates 9 f7 and f8 friction surfaces of guide plates 8 F10 friction surface of housing 1 wall 3 O-O housing 1 main axis P external force