RU101124U1 - ROPE SHOCK ABSORBER - Google Patents

Abstract

 1. A cable shock absorber containing an elastic element in the form of a spiral from a cable and the lower and upper support plates fixed on the spiral coils, characterized in that the upper support plate is fixed with an angular offset relative to the diametrical plane passing through the attachment point on the spiral coils of the lower support plate. ! 2. A cable shock absorber according to claim 1, characterized in that the angular displacement is 15-75 °. ! 3. The cable shock absorber according to claim 1, characterized in that it contains at least one additional spiral from the cable with the upper and lower support plates fixed to it, while the upper support plate is fixed to the turns of the additional spiral with an angular offset relative to the diametrical plane passing through the fixing point on the turns of an additional spiral of the lower base plate. ! 4. The cable damper according to claim 3, characterized in that the upper support plate is fixed on the turns of the additional spiral with an angular displacement in the direction from the main spiral. ! 5. The cable damper according to claim 3, characterized in that the upper support plate is fixed on the turns of the additional spiral with an angular displacement in the direction of the main spiral.

Description

The invention relates to machine components used to dampen vibrations with a loaded cable.

Known devices: vibration isolating support (ed. Certificate. SU 1588938, IPC ⁵ F16F 17/14, publ. 1990), cable shock absorber (ed. Certificate. SU 66768 M class ^2. F16F 17/14, publ. 1979 g. .) vibration damping support pat. EP 0059143 IPC F16F 17/14, publ. 1982), vibration damping support (US Pat. RU 2348840, IPC F16F 17/14 (2006.01), publ. 2009), cable shock absorber (US Pat. RU 2305809, IPC F16F 17/14 (2006.01), publ. 2007 .) containing the elastic element in the form of a spiral from a cable and the lower and upper support plates fixed on the coils at diametrically opposite points of the spiral.

The disadvantages of such designs are low bearing capacity, since the entire load force acts on the cable spiral in the radial direction and the complexity of manufacturing, which is explained by the difficulty of combining the fixing points of the support plates at diametrically opposite points of the spiral.

Closest to the claimed and adopted as a prototype is a cable shock absorber (US Pat. RU 2305809).

The objective of the proposed utility model is to increase the bearing capacity and simplify the manufacture of a cable shock absorber.

The problem is solved by improving the cable shock absorber containing an elastic element in the form of a spiral from a cable and the lower and upper support plates fixed on the spiral coils.

This improvement consists in the fact that the upper base plate is fixed with an angular offset relative to the diametrical plane passing through the fastening point on the spiral coils of the lower base plate, which increases the bearing capacity of the shock absorber due to the decomposition of the load force into horizontal and vertical components. In addition, the manufacture of such a shock absorber is simplified, since there is no need for forced displacement of the support plates relative to each other for their fastening at diametrically opposite points of the spiral.

In addition, the angular displacement can be 15 ° -75 ° - experimentally determined optimal value of the angular displacement.

In addition, the cable shock absorber may contain at least one additional spiral from the cable with the upper and lower support plates fixed on it, while the upper support plate is fixed on the turns of the additional spiral with an angular offset relative to the diametrical plane passing through the fixing point on the turns of the additional spiral of the lower base plate.

This embodiment allows to increase the bearing capacity of the cable shock absorber due to the load distribution between the main and additional spiral.

In addition, the upper support plate can be mounted on the turns of an additional spiral with an angular offset in the direction from the main spiral - an embodiment of a cable shock absorber that provides the required load direction and layout of the support assembly.

In addition, the upper support plate can be fixed on the turns of an additional spiral with an angular displacement in the direction of the main spiral - an embodiment of a cable shock absorber that provides the required load direction and layout of the support assembly.

The utility model is illustrated by drawings, where Fig. 1 shows a proposed cable shock absorber with one spiral, Fig. 2 - a proposed cable shock absorber with one spiral, side view, Fig. 3 - cable shock absorber with two spirals with an upper support plate fixed to an additional spiral with an angular displacement in the direction from the main spiral, Fig. 4 shows a cable shock absorber with two spirals with an upper support plate fixed to an additional spiral with an angular displacement in the direction of the main spiral.

The cable shock absorber contains an elastic element 1 in the form of a spiral from a cable and lower 2 and upper 3 support plates fixed on the spiral coils. The upper support plate 3 is fixed with an angular displacement α relative to the diametrical plane 4 passing through the attachment point A on the spiral coils of the lower support plate 2. It has been experimentally determined that the optimal angular displacement α is 15 ° -75 °. In the variants of FIGS. 2 and 3, the cable shock absorber comprises an additional spiral 5 from the cable with the upper and lower support plates 6 and 7 fixed to it, while the upper support plate 6 is fixed on the turns of the additional spiral 5 with an angular offset by an angle β relative to the diametrical plane 8 passing through the fixing point B on the turns of the additional spiral 5 of the lower support plate 7. In the embodiment of FIG. 2, the upper support plate 6 is fixed on the turns of the additional spiral 5 with an angular displacement β in the direction from the main spi rails 1. In the embodiment of FIG. 3, the upper support plate 6 is fixed on the turns of an additional spiral 5 with an angular displacement β in the direction of the main spiral 1.

The proposed utility model works as follows. When a load is applied to the upper support plate 3 (FIG. 1) or to the upper support plates 3 and 6 (FIG. 2 and FIG. 3) due to the angular displacement α (FIG. 1) or α and β (FIG. 2 and FIG. 3) the load force is decomposed into horizontal P _g and vertical P _into components, which increases the bearing capacity of the shock absorber. The choice of the optimal angles α and β depends on the operating conditions of the shock absorber. The manufacture of shock absorbers of this design is simplified by eliminating the operation of forced displacement of the support plates relative to each other.

Thus, the use of the proposed utility model can increase the bearing capacity and simplify the manufacture of a cable shock absorber.

Claims (5)

1. A cable shock absorber containing an elastic element in the form of a spiral from a cable and the lower and upper support plates fixed on the spiral coils, characterized in that the upper support plate is fixed with an angular offset relative to the diametrical plane passing through the attachment point on the spiral coils of the lower support plate. 2. A cable shock absorber according to claim 1, characterized in that the angular displacement is 15-75 °. 3. The cable shock absorber according to claim 1, characterized in that it contains at least one additional spiral from the cable with the upper and lower support plates fixed to it, while the upper support plate is fixed to the turns of the additional spiral with an angular offset relative to the diametrical plane passing through the fixing point on the turns of an additional spiral of the lower base plate. 4. The cable damper according to claim 3, characterized in that the upper support plate is fixed on the turns of the additional spiral with an angular displacement in the direction from the main spiral. 5. The cable shock absorber according to claim 3, characterized in that the upper support plate is fixed to the turns of the additional spiral with an angular offset towards the main spiral.