Friction shock absorber

Abstract

The invention relates to the field of transport mechanical engineering and concerns friction shock absorbers for vehicles. The object of the invention is to improve the operational life, performance and reliability of a friction shock absorber. The friction shock absorber comprises housing (1) with bottom (2) and with orifice (3) formed by walls (4), internal surfaces (fv) whereof form alternating working beds (V1) and connecting beds (V2), and further comprises friction assembly (5) consisting of pressure wedge (6) and stay wedges (7) in contact with same, said stay wedges being provided with friction surfaces (fp), while return-and-retaining device (8) is located between bottom (2) and friction assembly (5). In addition, the area (S1) of contact between friction surfaces (fp) of stay wedges (7) and internal surfaces (fv) of walls (4) of orifice (3) in working beds (V1) exceeds the corresponding area (S2) of contact in the connecting beds (V2). The internal surfaces (fv) may be straight, while the values of angles (θ1) between adjacent internal surfaces (fv), which form working beds (V1), are lower than the values of angles (θ2) between adjacent internal surfaces (fv), which form the connecting beds (V2). The thickness of walls (4) of the orifice (3) is variable with an increase in the direction from the working bed (V1) to the connecting bed (V2). The contact between pressure wedge (6) and stay wedges (7) is provided along linked curved surfaces (fκ).

Claims

1. Friction shock absorber comprises housing (1) with bottom (2) and with orifice (3) formed by walls (4), internal surfaces (fv) whereof form alternating working beds (V1) and connecting beds (V2), and further comprises friction assembly (5) consisting of pressure wedge (6) and stay wedges (7) in contact with same, said stay wedges (7) being provided with friction surfaces (fp), adjacent to the internal surfaces (fv) of walls (4) of orifice (3), while return-and-retaining device (8) is located between bottom (2) and friction assembly (5), wherein the area (S1) of contact between friction surfaces (fp) of stay wedges (7) and internal surfaces (fv) of walls (4) of orifice (3) in working beds (V1) exceeds the corresponding area (S2) of contact in the connecting beds (V2), wherein thickness of walls (4) of the orifice (3) is variable with an increase in the direction from the working bed (V1) to the connecting bed (V2).

2. Friction shock absorber according to claim 1, wherein the internal surfaces (fv) of walls (4), which form working beds (V1) and connecting beds (V1), are straight and form angles (θ1, θ2) between each other.

3. Friction shock absorber according to claim 2, wherein the values of angles (θ1) between adjacent internal surfaces (fv), which form working beds (V1), are lower than the values of angles (θ2) between adjacent internal surfaces (fv), which form the connecting beds (V2).

4. Friction shock absorber according to claim 1, wherein return-and-retaining device (8) is provided with supporting plate (9) in contact with stay wedges (7).

5. Friction shock absorber according to claim 1, wherein hard lubricant inserts (10) are available between stay wedges (7) and walls (4) of orifice (3).

6. Friction shock absorber according to claim 1, wherein hitches (11) are provided in the walls (4) of orifice (5) on connecting beds (V2).

7. Friction shock absorber according to claim 1, wherein said contact between pressure wedge (6) and stay wedges (7) is provided along linked curved surfaces (fκ).

Description

(1) The utility model is further described in detail with reference to the accompanying figures, wherein:

(2) FIG. 1 shows the top view of the friction shock absorber according to the invention;

(3) FIG. 2 shows a longitudinal section A-A according to FIG. 1, wherein the friction shock absorber is in the initial position;

(4) FIG. 3 shows a longitudinal section A-A according to FIG. 1, wherein the friction shock absorber is in fully compressed position;

(5) FIG. 4 shows isometric projection of the housing of the friction shock absorber;

(6) FIG. 5 shows a stay wedge of the friction assembly;

(7) FIG. 6 shows the top view of an embodiment of the orifice of the housing of the friction shock absorber with a broken-out section view;

(8) FIG. 7 shows view B of a stay wedge, installed in a working bed, according to FIG. 6;

(9) FIG. 8 shows view C of a stay wedge, installed in a connecting bed, according to FIG. 6;

(10) FIG. 9 shows the top view of a deteriorated housing of the friction shock absorber.

(11) The friction shock absorber (FIG. 1-3) comprises housing 1 with bottom 2 and with orifice 3 formed by walls 4, the internal surfaces fv whereof form alternating working beds V1 and connecting beds V2, and further comprises friction assembly 5 consisting of pressure wedge 6 and stay wedges 7 in contact with same. Said stay wedges 7 are provided with friction surfaces fp, while return-and-retaining device 8 is located between bottom 2 and friction assembly 5. The profile, the internal surfaces fv whereof form working beds V1 and connecting beds V2, is implemented in such a way, that the area S1 of contact between friction surfaces fp of stay wedges 7 and internal surfaces fv in working beds V1 exceeds (FIGS. 6, 7) the corresponding area S2 of contact in the connecting beds V2 (FIGS. 6, 8).

(12) The return and retaining device 8 (conventionally shown by crossed straight lines in FIGS. 2 and 3) may be represented by compression springs, or it may be designed as a stack of resilient and elastic elements, similarly to the prior art shock absorber. Return-and-retaining device 8 is in contact with stay wedges 7 and may be provided with supporting plate 9 at the place of such contact.

(13) In order to reduce the rate of deterioration of walls 4 of orifice 3 of housing 1, and to increase operational stability of the friction shock absorber, it is advantageous to install hard lubricant inserts (10) between walls 4 and stay wedges 7 (FIG. 2-4).

(14) The different profiles of the working beds V1 and the connecting beds V2 result in variable thickness of walls 4. The lowest thickness is at the working beds V1, having the value of a (FIGS. 6,9), and it gradually increases in the direction of the connecting beds V2 till it reaches its greatest value b. Under the conditions of operation of the friction shock absorber with the horizontal main axis O, the deterioration of the walls 4 is uneven (FIG. 9) due to gravity forces F. A significant advantage over the prior art shock absorber is lower deterioration in the areas having thickness a and higher deterioration in the areas having thickness b. It means that the residual wall thickness tends to equalize over time and remains sufficient for the operational suitability of the shock absorber housing, which is not observed in the prior art.

(15) Different profiles of the working beds V1 and the connecting beds V2 provide for an increase in the transmission coefficient of the friction shock absorber, which directly leads to an increase in its power capacity. A more illustrative example of different profiles of working beds V1 and connecting beds V2 is an embodiment, wherein the internal surfaces fv of walls 4, which form said beds, are straight (FIG. 1). In this case, the values of angles θ1 between adjacent internal surfaces fv, which form working beds V1, are lower than the values of angles θ2 between adjacent internal surfaces fv, which form the connecting beds V2.

(16) Uneven deterioration of the walls 4 due to gravity forces F (FIG. 9) and the displacement of the friction assembly in the direction of these forces may result in gaps occurring between at least one of the spacer wedges 7 and the pressure wedge 6, which can negatively affect friction shock absorber performance. Therefore, it is advantageous when the linked surfaces fκ of contact between stay wedges 7 and pressure wedge 6 are curved, which will prevent the displacement of these parts relative to each other, and will increase the area of their mutual contact and the performance of the friction shock absorber.

(17) The operating principle of the friction shock absorber is based on the fact that return-and-retaining device 8 is compressed, when external force Q (FIG. 3) is applied to pressure wedge 6 at the side of the automatic coupling device when the cars collide.

(18) Pressure wedge 6 brings stay wedges 7 inside housing 1 with the friction surfaces fp rubbing along the inner surfaces fv of walls 4 of orifice 3 in the working beds V1, as well as along the linked contact surfaces fκ of contact between stay wedges 7 and pressure wedge 6. The impact energy, caused by an external force Q, is intensively absorbed and dissipated in the form of heat.

(19) When the friction shock absorber is no longer exposed to the external force Q, return-and-retaining device 8 is released, pushing friction assembly 5 in its initial position (FIG. 2) until pressure wedge 6 is stopped by hooks 11 on housing 1 in the zone of the connecting beds V2.

REFERENCES

(20) Patent U.S. Pat. No. 6,478,173, IPC B61G9/10; B61G11/14; B61G9/18; B61G9/06, priority date Feb. 13, 2001, publication date Nov. 11, 2002/prior art/.

(21) TABLE-US-00001 LIST of reference designations and elements to which they refer Item No. ELEMENT 1 housing 2 bottom of housing 1 3 orifice of housing 1 4 wall of housing 1 5 friction assembly 6 pressure wedge 7 stay wedge 8 return-and-retaining device 9 supporting plate 10  hard lubricant insert 11  hitch V1 working bed V2 connecting bed Q external force F gravity forces O main axis fp friction surface of stay wedge 7 fκ linked contact surfaces of pressure wedge 6 and stay wedges 7 fv internal surfaces of walls 4 a thickness of wall 4 at working bed V1 b thickness of wall 4 at connecting bed V2 S1 contact area of stay wedges 7 in working beds V1 S2 contact area of stay wedges 7 in connecting beds V2 A-A designation of the integrated frontal section per FIG. 1 Θ1 angle between the internal surfaces fv, which form working beds V1 Θ2 angle between the internal surfaces fv, which form connecting beds V2 B, C views per FIG. 6