RU186458U1 - VIBRATION ISOLATING SYSTEM - Google Patents

Abstract

The utility model relates to mechanical engineering, in particular to vibration-isolating systems. The vibration-isolating system contains a transition metal plate mechanically connected with at least four shock absorbers to the foundation of the object, and additional vibration-isolating devices mechanically connected to the transition plate and working equipment, each of the vibration-isolating devices contains a rigid case, rubber bushings, support washers, a rigid rod mechanically connected to the equipment and through rubber sleeves to the device body, which is rigidly connected to the adapter plate. Additional vibration isolating devices are located in the through cavities of the adapter plate in the quantity n = i + 1, where i = 3, 5, 7 ..., determined by the required static and dynamic characteristics of the system, and are mounted in the through cavities to the adapter plate from its opposite side from the equipment. The technical result is an increase in the effectiveness of vibration isolation while maintaining the overall mass characteristics of the system with a single-stage equipment mounting scheme. 5 ill.

Description

The utility model relates to mechanical engineering, in particular to vibration-isolating systems for technological equipment that creates vibrational vibrations at an object that exceed permissible values.

Known vibration isolation systems for technological equipment, containing at least four vibration isolators and a transition plate, reducing the vibration effect of working equipment on the building structure and maintenance personnel (RF Patent for the invention No. 2077795, F16F 7 \ 00, Kochetov OS 1997 .; Electric fans RCC Specifications TU 5.475-16104-86, 1986, sheet 66)

A disadvantage of the known single-stage vibration isolating system is the limited ability to reduce the impact of vibrational vibrations of the equipment on the object in a wide range of frequencies.

Closest to the proposed vibration-isolating system, the technical essence is a vibration-isolating system to reduce the vibration of electrical equipment (a centrifugal electric fan), which is an intermediate frame, which is connected through the vibration isolators of the second fastening cascade to the foundation of the object and on which a centrifugal electric fan is installed through the vibration isolators of the first fastening cascade (L. V. Pozdeev, A.G. Mikhailov, V.A. Timoshenko - The effect of a modification of the design of a two-stage shock absorbing cre Lenia on vibroaktivnosti marine centrifugal electric fans. Proceedings of TPU, T. 319 №2, pp. 26-29).

A disadvantage of the known vibration-isolating system is the relative bulkiness and limited structural rigidity, causing increased vibration activity of the transition frame and the presence of additional resonant frequencies in the system.

The technical result of the proposed vibration-isolating system is to provide additional effective vibration isolation of the forced oscillations of the equipment at medium and high frequencies while maintaining the overall mass-dimensional characteristics of the system with a single-stage equipment mounting scheme.

In the proposed utility model, the indicated technical result is achieved in that the vibration-isolating system comprises a transition metal plate mechanically coupled with at least four shock absorbers to the foundation of the object and additional vibration-isolation devices mechanically connected to the transition plate and working equipment, each of which is vibration-isolating devices contains a metal case, rubber bushings, thrust washers, a metal rod mechanically connected to the equipment and through rubber novye bushings with the housing of the device, which is rigidly connected with the adapter plate, while additional vibration-isolating devices are located in the through cavities of the adapter plate in the amount n = i + 1, where i = 3, 5, 7 ..., determined by the required static and dynamic characteristics of the system, and are mounted in through cavities to the adapter plate on its opposite side from the equipment.

In FIG. 1.2 is a structural diagram of the proposed vibration-insulating system of an electric fan (working equipment), relatively close to a single-stage depreciation scheme for weight and size characteristics, providing an increase in the quality of vibration damping of equipment at the facility.

The vibration-isolating system contains a metal adapter plate 1, mechanically connected with at least four shock absorbers 2 to the foundation of the object 3 (Fig. 1a, b) and additional vibration-isolating devices 4, mechanically connected to the adapter plate 1 and working equipment 5, each of vibration-isolating devices 4 contains a metal body 6, rubber bushings 7, thrust washers 8, a metal rod 9 (Fig. 2a, b, c), rigidly connected to equipment 5 and through rubber bushings 7 to the housing 6, which is rigidly connected to the transition plate 1, while additional vibration-isolating devices 4 are located in the through cavities 10 of the adapter plate 1 in the amount n = i + 1, where i = 3, 5, 7 ..., determined by the required static and dynamic characteristics of the vibration-isolating system, and are mounted in the through cavities 10 to the adapter plate 1 on its opposite side from the equipment 5, which paws 11 (Fig. 1) is rigidly connected to the metal rods 9 of the vibration isolation devices 4.

Vibration isolating devices 4 can be constructed according to a well-known technical solution (RF patent for utility model No. 170717, IPC F16F 1 \ 371, N.I. Podlevsky, published on 05/04/2017, Bull. No. 13), which ensures reliable fastening of the equipment and its protection from disruption under dynamic impacts.

To simplify the technology of assembly and repair of the vibration-isolating system, the metal rods 9 are made in the form of pins, rigidly connected with transition metal legs 12 (Fig. 2a, b), on which equipment 5 (Fig. 1) is rigidly mounted using the legs 11 and bolts 13 after of the fact that the adapter legs 12 and the adapter plate 1 will be mechanically connected by vibration isolating devices 4, which are mounted on the rods (studs) 9 in the cavities 10 (Fig. 2) of the plate 1 from its opposite side from the equipment 5. This allows the vibration isolation to be repaired. 4 devices in turn without complete dismantling of the equipment and the vibration isolating system.

The proposed vibration-isolating system allows for more efficient damping of forced vibrations of equipment along all axes, with insurance against equipment breakdown under shock loads.

Indeed, when the housings 6 of the vibration isolation devices 4 are rigidly fixed to the adapter plate 1 in the cavities 10 and the equipment 5 is attached using the adapter legs 12 and rods 9 to the vibration isolation devices 4, a mechanical connection is formed between the equipment 5 and the adapter plate 1 through elastic-dissipative elements - rubber bushings 7, in which the energy dissipation of forced oscillations of the equipment additionally occurs due to hysteresis losses inside the elastically dissipative elements. The composition of the rubber mixture of elements 7, the choice of one or another rubber composition affects mechanical losses (tan δ is the tangent of the mechanical loss) and is determined by the specific task of additional damping of equipment vibration.

In practice, when using AC executive motors with a shaft rotation speed of 3000 rpm, there is a need for vibration damping at frequencies of 50 Hz and higher.

The efficiency of damping of equipment vibrations when it is installed on vibration-isolating devices with rubber elastic-dissipative elements is characterized by the ratio

where L _ν - the required decrease in the amplitude of vibration, dB; ƒ - frequency of vibrational vibrations, Hz; ƒ _o - natural frequency of the equipment, Hz.

эффективность демпфирования будет оптимальной по коэффициенту передачи и эксплуатационным характеристикам виброизолирующих устройств. Поэтому для демпфирования вибраций с частотой 50 Гц и выше необходимо определять размеры устройств, их количество, состав резиновой смеси упруго-диссипативных элементов ориентируясь на собственную частоту свободных колебаний оборудования на виброизолирующих устройствах в пределах 10-15 Гц:With the ratio

damping efficiency will be optimal in terms of transmission coefficient and operational characteristics of vibration isolating devices. Therefore, to damp vibrations with a frequency of 50 Hz and above, it is necessary to determine the dimensions of the devices, their number, and the composition of the rubber mixture of elastic-dissipative elements, focusing on the natural frequency of free vibrations of equipment on vibration-isolating devices within 10-15 Hz:

where k is the total stiffness, N / m, m is the total mass, kg

In this case, the general static deformation of vibration isolating devices

(Lyapunov V.P., Lavendell E.E., Shlyapnikov S.A. Rubber vibration isolators. L .: Shipbuilding, 1988.)

Based on the foregoing, for effective vibration damping of equipment at medium and high frequencies with a nominal weight of, for example, 400 kg, it is sufficient to provide static deformation of additional vibration isolation devices of 1.5-2 mm and the resonant frequency of equipment with a vibration isolation system that practically does not cause difficulties in implementation, when using additional vibration-isolating devices with bushings made of rubber compound, for example, of the brand (IRP-1347; - 1346) with the overall dimensions of the devices 60 × 60 × 40 mm and their total number TBE 14-18 pcs.

To ensure that the center of mass of the equipment and the center of stiffness of the vibration isolators are aligned vertically, the vibration isolating devices may be unevenly located in the plane of the adapter plate

Using the proposed vibration-isolating system allows to obtain a technical and economic effect by reducing its weight and size indicators and more effective damping of equipment vibration at medium and high frequencies.

Claims (2)

1. A vibration-isolating system comprising a transition metal plate mechanically coupled with at least four shock absorbers to the foundation of the object, and additional vibration isolation devices mechanically coupled to the transition plate and work equipment, each of which contains a metal body, rubber bushings, support washers, a metal rod mechanically connected to the equipment and through rubber bushings with the device body, which is rigidly connected to the adapter plate, characterized in that up to Additional vibration-isolating devices are located in the through cavities of the adapter plate in the amount n = i + 1, where i = 3, 5, 7 ..., determined by the required static and dynamic characteristics of the system, while the vibration-isolating devices are mounted in the through cavities of the adapter plate from its opposite side equipment and can be dismantled during the repair and replacement of the rubber bushings of the device separately, eliminating the need for complete dismantling of the equipment and vibration isolation system. 2. The vibration-isolating system according to claim 1, characterized in that the additional vibration-isolating devices, for the purpose of vertical alignment of the center of mass of the equipment and the center of stiffness of the vibration isolators, are not uniformly located in the plane of the adapter plate.

Images