SU1059321A1 - Spring rate corrector - Google Patents

Abstract

HARDNESS CORRECTOR, containing guides of the protected and vibrating objects, interconnected, springs attached to the vibrating object, an axially movable slider installed with a possibility of fixation in different positions, into prismatic knives connecting the springs with the movable slider, characterized in that, in order to reduce the dynamic forces, the guides 1; are made in the form of telescopically arranged tubes, the corrector is provided with a spring and a pair of free-wheeling mechanisms, each of which is located It can be installed in the pipe of the object to be protected and is made in the form of a spring-wedge, in contact with it of an axially spring-loaded ball and control plate, which interacts with the end surface of the same pipe.

Description

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The invention relates to mechanical engineering and can be used in all fields of the native household where protection against vibrations is required, for example, in suspensions of power shipboard equipment,

A stiffness corrector is known, containing guides of the object being protected and vibrating, interconnected, springs fixed and vibrating object, an axially movable slider, installed with the possibility of fixation in different positions and prismatic knives, connecting springs with movable slider 1. The disadvantage of this corrector is. that in the process of its adjustment to the measuring load, it is disconnected from work at the moment of landing the sliders on their travel stops, when the working forces are maximal. The sudden shutdown of the device from work and the disappearance of its corrective efforts leads to a deterioration of the vibration-protective properties of the suspension. The aim of the invention is to reduce the dynamic forces by adjusting the offset in its middle position when its working forces are zero. This goal is achieved by the fact that the stiffness corrector contains guides of the protected and vibrating objects. interconnected springs fixed on a vibrating object, a movable axial direction of the slider mounted with a possibility of fixing {And in different positions, and prismatic knives connecting springs with a movable slider, guiding made in the form of telescopically located -rubs, the corrector is equipped with a spring and a pair of free-wheeling mechanisms, each of which is located in the pipe of the protected object and is made in the form of a spring-loaded wedge in contact with the ball spring-loaded in the axial direction and control the lath interacting with the end surface of the same pipe. The drawing shows the stiffness corrector, a general view in section. The stiffness corrector contains the guide 1 of the vibrating object and the guide 2 of the protected object made in the form of telescopically arranged tubes. Springs 3 are vertically mounted on the guide 1, which are connected with a movable slider 5 using prismatic knives 4. In the internal cavity, a pair of free-running mechanisms (MSH) each of which consists of a wedge 6 fixed in the guide 2 using the ball 7 and the springs 8, the control bar 9, with the protrusion 10 interacting with the stop II mounted on the end of the guide shaft I. The freewheel mechanisms are pressed against the movable slider S with the help of the spring 12.-.

The stiffness corrector works as follows.

With a constant load P of the suspension and with oscillations of the guide 1 of the vibrating object, the guide 2 of the protected object with children 5–9 and 12 will remain stationary, and the prismatic knives 4 will make a rolling motion around their contact points with the sliding slide 5, providing the necessary corrective effect on the stiffness of the vibration damper. The stops And at the same time they reach the protrusions 10, since their calculated motion between the projections 10 exceeds the possible range of oscillations of the guide 1 of the vibrating object. When the load P and the oscillation of the vibrating object's guide 1 change (for example, as it increases), the corrective action of prismatic iozha 4 is carried out continuously, since with each downward oscillation movement the stop 11 moves the lower fur back some distance down and the movable slider 5. This gap is filled by moving the movable slider 5 down, but not immediately, but at the moment when the prismatic images of the 4 are approaching their horizontal position. At this moment, the vertical component of the forces of the springs 3 tends to zero and it cannot cause dynamic effects, deterioration. Suspension vibration 1e properties of the suspension. The downward movement of the movable slider 5 is carried out under the action of a spring 12, which at the same time raises and moves down the upper MCX. When the object oscillates again and again, the stop And again, moves the lower MSC down and the adjustment cycle of the corrector is repeated. This will continue as long as the suspension load increases. When the load P is reduced, the elastic element of the suspension lengthens and the guide 1 vibrates its object with the first oscillatory movement upward by the support 11 aside. pushes behind the protrusion 10 of the control bar 9 of the upper MA. The sequence of the stiffness corrector will be similar to that discussed above. Stiffness corrector; installed, for example, in the engine mount, it allows the dynamic forces to be increased by more than 200 times and to reduce the rigidity of the sub- to zero.

Claims (1)

RIGIDITY CORRECTOR, containing guides of the protected and vibrating objects, interconnected, springs fixed on the vibrating object, axially movable slider mounted with the possibility of fixation in various positions, in prismatic knives, connecting springs with a movable slider, characterized in that, in order to reduce dynamic forces, the guides are made in the form of telescopically arranged pipes, the corrector is equipped with a spring and a pair of free-wheeling mechanisms, each of which is located in the pipe of the protected object and is made in the form of a wedge pulled by a spring, a ball contacting it in an axial direction ⁴ and a control bar interacting with the end surface of the same pipe. ABOUT SI SOU>