SU808626A1 - Dynamic oscillation damper - Google Patents

Description

The invention relates to construction and is intended to reduce the amplitude of oscillations of high-rise buildings, which ensures their normal operation, and therefore, durability.

A dynamic vibration damper of buildings and structures is known, including an inertial mass mounted on a horizontal platform with thrust bearings and a damping device in the form of bellows with chokes [1].

The well-known damper is designed to damp the vibrations of structures with a small amplitude (high frequency) and 15 small mass. The use of this damper for structures with large mass and amplitude of vibration is unacceptable IE-ea the possibility of constructive execution in kind of bellows ®, respectively, with the necessary rigidity and linear stiffness characteristic.

The closest technical solution to the proposed one is a dynamic vibration damper, including a shaft with an axisymmetric mass rigidly fixed on it, the center of gravity of which is located on the shaft axis, and its supporting ends are mounted on curved 30 linear guides with the possibility of moving along him [2].

The disadvantage of the absorber is its lack of effectiveness, due to the lack of a damping device designed to dissipate the energy accumulated by the inertial mass.

The purpose of the invention is to increase the efficiency of the absorber by achieving optimal damping.

This goal is achieved by the fact that a dynamic vibration damper, including a shaft with an axisymmetric mass rigidly fixed on it, whose center of gravity is located on the shaft axis, and its ends are mounted on curved guides attached to the supporting surface with the ability to move along them, is equipped with a damping device in the form '' weights connected to the shaft using flexible elements.

Variants of a damper are provided, in which the loads are made in the form of shoes in contact with the supporting surface, and the flexible elements are pivotally connected to the centers of the shaft ends.

In this case, the shaft can be covered by flexible elements at least once, forming branches, and loads are suspended at the ends of each of the branches of flexible elements.

In addition, the mass is spirally covered at least once by flexible elements.

In FIG. 1 shows a damper with a damping device, in which the loads are made in the form of shoes, a general view; in FIG. 2 is a view AA in FIG. 1; in FIG. 3 - damper with flexible elements spirally covering the shaft; in FIG. 4 is a view of BB in FIG. 3; in FIG. 5 - damper with flexible elements covering the mass; in FIG. 6 is a view BB of FIG. 5.

The dynamic vibration damper includes a shaft 1 with an axisymmetric mass 2 rigidly fixed on it, the center of gravity 3 of which is located on the axis; 4 shafts 1. The ends of the shaft 1 are mounted on curved guides 5 attached to the supporting surface 6. The damper is provided with loads in the form of shoes 7 in contact with the supporting surface 6. The working surface of the shoes 7 and the supporting surface at the point of contact with the shoes may have a curved shape and coated with a friction material having a significant coefficient of friction, for example, Ferrado. The shoes 7 are connected to both ends of the shaft 1 using flexible elements 8, the free ends of which are yen with the centers of the ends of the shaft 1 using hinges 9.

An embodiment of the body is possible, according to which flexible cops 8 cover at least once the shaft 1, forming branches, to the ends of which loads 7 are suspended.

In addition, the flexible elements 8 at least once cover the axisymmetric mass 2. To hold the flexible elements 8 on. mass 2 on it bearers. '

Work as follows

When performing a damper with loads; In the form of shoes in contact with the supporting surface, flexible elements are pivotally connected to the centers of the waf ends in antiphase with it, accumulating energy. When moving (rolling) the inertial mass along the guides, it pulls the shoes along with it using flexible elements pivotally connected to the shaft.

In the case of rigid attachment to the shaft, the flexible elements would be wound together with the extinguishing element, the circles reinforcing the absorber guard45 are carried out in a manner.

on the shaft, tearing off the shoes from the surface with which they should be in contact. When the shoes rub against the supporting surface, energy is scattered. The friction force can be adjusted ^; by changing the weight of the shoes, and therefore, optimum attenuation can be achieved.

In the case of a damper according to the variants according to which the shaft or ¹ axisymmetric mass is spirally covered by flexible elements at least once by the formation of branches, the damping of oscillations is caused by the bending of the branches of flexible elements pulled by loads. In this case, the cargo captures the inertial mass of the damper.

Optimum attenuation can be achieved by changing the size of the cargo and the number of turns of flexible elements.

Claims (2)

The invention relates to construction and is intended to reduce the amplitude of vibrations of high-rise structures, which ensures their normal operation and, consequently, their durability. A dynamic vibration damper of buildings and structures is known, including an inertial mass mounted on a horizontal platform on the bearings, “a damping device in the form of bellows with throttles l7. The known damper is designed to dampen vibrations of structures with a small amplitude (high frequency) and a small mass. The use of this extinguisher for structures with large mass and amplitude of oscillations is unacceptable due to the possibility of constructive implementation of the bellows in nature, respectively, with the necessary rigidity and linear stiffness characteristic. The closest technical solution to the present invention is a dynamic oscillation damper, including a shaft with an axisymmetric mass rigidly fixed on it, the center of gravity of which is located on the shaft axis, and its supporting ends are mounted on curved rails with the possibility of moving along them 2 The disadvantage of a quencher is its lack of efficiency due to the lack of a damping device designed to dissipate the energy accumulated by the inertial mass. The purpose of the invention is to increase the efficiency of the quencher due to the achievement of optimal damping of vibrations. This goal is achieved by the fact that a dynamic oscillation damper, including a shaft with an axisymmetric mass rigidly attached to it, the center of gravity of which is located on the shaft axis, and its ends are mounted on curvilinear guides attached to the support surface, is damped with a device in the form of cargoes, connected with a veshom using flexible elements. There are options for the execution of the quencher, for which the weights are made in the form of shoes, contacting with the supporting surface, and the flexible elements are pivotally connected to the centers of the ends of the High. In this case, the shaft can be covered with flexible elements at least once, forming a branch, and the weights are suspended at the ends of each of the branches of flexible elements. In addition, the mass is spirally covered at least once by flexible elements. FIG. 1 shows a damper with a damping device, in which the loads are made in the form of shoes, a general view; in fig. 2 is a view A-A in FIG. one; in fig. 3 — a damper with flexible elements spirally enclosing the shaft in FIG. 4 is a view of BB in FIG. 3; in fig. 5 - damper with flexible elements covering the mass; in fig. 6 is a view B-B in FIG. 5. A dynamic oscillation damper includes a shaft 1 with an axisymmetric mass 2 rigidly fixed on it, whose center of gravity 3 is located on the axis 4 of shaft 1. The ends of shaft 1 are mounted on curved guides 5 attached to the supporting surface 6. The damper is supplied with weights the shape of the shoes 7 in contact with the support surface 6. The working surface of the shoes 7 and the support surface at the point of contact with the shoes may have a curvilinear shape and covered with friction material having a significant coefficient of friction, for example, Ferrado. The shoes 7 are connected to both ends of the shaft 1 by means of flexible elements 8, the free ends of which are connected to the centers of the ends of the shaft 1 by means of hinges 9. A variant of the damper is possible, according to which the flexible elements 8 span at least once a shaft 1, to form a branch, to the ends of which the weights 7 are suspended. In addition, the flexible elements 8 at least once span the axisymmetric mass 2. To hold the flexible elements 8 on the mass 2 on it circumferentially reinforce the restraints. The work of the extinguisher is carried out in the following way. When extinguishing a quencher with weights; In the form of the shoes in contact with the supporting surface, the flexible element is pivotally connected to the centers of the ends in the opposite phase with it and accumulates. When moving (rolling) the inertial mass along the guides it is not behind them the shoes with the help of flexible elements pivotally connected to the shaft. In the case of rigid attachment to the shaft, the flexible elements would be wound on the shaft, tearing off the shoes from the surface with which they should contact. When the shoes rub against the bearing surface, energy is dissipated. The frictional force can be adjusted by changing the weight of the shoes, and consequently, an optimal damping can be achieved. If the damper is made according to the variants according to which the shaft is axisymmetric mass is spirally covered by flexible elements, at least once the formation of branches, the damping of oscillations is caused by the bending of the branches of flexible elements that are pulled by loads. In this case, the cargo captures the inertial mass of the quencher. Optimal damping can be achieved by varying the size of the weights and the number of turns of the flexible elements. Claim 1. Dynamic oscillation damper, including a shaft with an axisymmetric mass rigidly attached to it, the center of gravity of which is located on the shaft axis, and its ends are mounted on curved rails attached to the supporting surface, such as . and with the fact that, in order to increase the efficiency of the damper by achieving optimal damping of the oscillations, the damper is equipped with a damping device in the form of loads connected to the shaft or weight using flexible elements. . 2. The damper according to claim 1, is also distinguished by the fact that the weights are made in the form of shoes in contact with the supporting surface, and the flexible elements are connected pivotally with the centers of the shaft ends. 3. A damper pop, 1, characterized in that the shaft is spirally covered with flexible elements at least once to form branches, and the weights are suspended at the ends of each of the branches of flexible elements. 4. Damper pop. 1, in that the mass is spirally enveloped at least once by flexible elements. Sources of information taken into account during the examination 1. USSR author's certificate No. 379757, cl. E 04 B 1/98, 1969. 2. The patent of the Federal Republic of Germany 1281294, cl. 65 A 39/02, published. 1967. Y f Pue. I iput.j h, l Y5 at / / / Put.5 5-6 ) AT 7 Vut. f