SU1310544A1 - Vibration damper - Google Patents

Abstract

The invention relates to the field of mechanical engineering, in particular, to means of damping vibrations. The aim of the invention is to increase vibration damping by expanding the range of operating frequencies. The vibration absorber 5 located in the vibration damper cavity 2, cavity 7, whose axis is inclined to the damper axis at an angle of 35-50, and accommodates in this cavity a spring-loaded With its ability to move along its axis, the piston 9 allows the absorber to be put into operation at resonant oscillations of the padded structure and off from work at pre- and resonant frequencies. 2 Il. with SP 4 ;;;. it fie.1

Description

The invention relates to mechanical engineering, in particular to means of damping vibrations.

The aim of the invention is to increase the efficiency of damping due to the expansion of the operating frequency range.

In Fig.1 schematically shows the proposed damper; figure 2 - section aa in figure 1.

The vibration damper contains a cantilever resilient hollow rod 2 rigidly attached to the vibrating structure 1 and placed in its cavity and. spring-loaded elastic element 3 to the cavity walls and elastic element 4 to the vibrating structure 1 vibration absorber 5, in which a cylindrical cavity 7 limited by end walls 6 is made, the axis of which is inclined to the axis of the rod 2 at an angle of 35-50, and in cavity 7 placed with the ability to move

pull along its axis and spring-loaded elastic element 8 to one of the walls 6 of the piston 9.

The vibration damper works as follows.

Under the action of vibration from the side of the structure, the cantilever resilient hollow rod 2, and with it the piston 9, also begin to oscillate. Since the piston 9 is at an angle to the longitudinal axis of the rod 2, the absorber 5 has an internal structural asymmetry, which leads to change in dependence. on the vibration vibration frequency FR of the effective friction coefficients f and f at the contact of the absorber 5 with the rod 2, respectively, in directions A and B (figure 1). And in the frequency range of 0.6K-ico "il J1K, where K is the frequency

25

thirty

35

40

0,, 1.

Thus, when an oscillation damper is operated in the resonant frequency range, the absorber 5 moves in the direction B, overcoming the resistance of the elastic element 4, and is located in the extreme position at the free end of the rod 2. In this case, the oscillation damper has the maximum dynamic effect on the vibration-proof structure 1 and suppresses resonant oscillations.

With an increase in the frequency of the disturbance to a value of co i 1,1K, i.e. frequency, when the oscillation damper begins to work in the resonance region, a change in the direction of movement of the absorber 5 occurs, and the latter moves in the direction A. The elastic force also contributes to this displacement

natural oscillations of the piston 9 on up. element 4. In this frequency diapar element 8, the effective coefficient of friction in direction B of the bolzone absorber 5 occupies the leftmost position (as shown in FIG. 1), and the vibration damper is completely turned off from operation, which reduces the harmful dynamic effect on design 1 and therefore, it improves the efficiency of vibration isolation. .

more than in direction A, i.e. f f а in the frequency range 1, 1, 7К, on the contrary, the effective friction coefficient is greater in the direction A, i.e. f d fgj. The presence of internal structural asymmetry and the difference in effective friction coefficients in the direction A and B lead to the fact that when the vibration is applied to the hollow rod 2, the absorber 5 is massaged in the horizontal plane in the cavity of the rod 2.

five

0

five

0

five

0

Moreover, in the frequency range 0, bK., 1K, the absorber 5 moves in the direction A, and in the frequency range 1,, 7K in the direction B. The change in the direction of movement of the absorber 5 occurs at a frequency of CO 1.1K.

The presence of the elastic element 3 provides a stable movement of the absorber 5 when changing in a significant range of intensity of vibration, because at a high level it does not break the contact of the absorber 5 with the rod 2.

The natural frequency of oscillations K of piston 9 is chosen such that, when the structure 1 oscillates in the resonance frequency range, the ratio of the vibration frequency c to the natural vibration frequency K of the piston 9 is in the range 1, 1К, 7К, and in the resonance frequency range this ratio was in range

0,, 1.

Thus, when an oscillation damper is operated in the resonant frequency range, the absorber 5 moves in the direction B, overcoming the resistance of the elastic element 4, and is located in the extreme position at the free end of the rod 2. In this case, the oscillation damper has the maximum dynamic effect on the vibration-proof structure 1 and suppresses resonant oscillations.

With an increase in the frequency of the disturbance to a value of co i 1,1K, i.e. frequency, when the oscillation damper begins to work in the resonance region, a change in the direction of movement of the absorber 5 occurs, and the latter moves in the direction A. The elastic force also contributes to this displacement

. element 4. In this frequency range

50

In the zone, the absorber 5 occupies the extreme left position (as shown in FIG. 1), and the vibration damper is completely turned off from operation, which reduces the harmful dynamic effect on structure 1 and, therefore, improves the efficiency of vibration insulation. .

Thus, due to the automatic activation and deactivation of the vibration damper, high vibration protection is achieved in a wide frequency range.

Claims (1)

Invention Formula A vibration damper containing a cantilever resilient hollow rod rigidly attached to the vibrating structure, placed in its cavity and springed to it and to the vibrating structure, a vibration absorber, characterized in that, in order to increase the efficiency of damping vibrations due to the expansion of At the operating frequency range, a cylindrical cavity limited by end walls is made in the vibration absorber, the axis of which is inclined to the axis of the rod at an angle of 35-50, and the vibration damper is equipped with a piston placed in the cylindrical cavity that can be moved along its axis and spring-loaded to one of its end walls . fi & .2 Editor E. Sligan Compiled by E. Neselovska Tehred M. Khodanich Proofreader G. Reshetnik Order 1876/31 Circulation 812 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4