DD297494A5 - VERSION VIBRATION INSULATOR AND DAMPER - Google Patents

Abstract

The invention relates to a Verspannschwingungsisolator and -daempfer for fundamental vibration-insulated and -gedaempften installation of machinery and equipment, characterized in that a cone is clamped in a viscoelastic body by manual bracing and / or by the load or part load of the machine or plant according to the wedge principle , The natural frequency behavior of this vibration isolator and absorber depends on the size of the stress and the friction behavior between the cone and the viscoelastic body. The spring properties are variable by inserting a viscous and / or viscoelastic and / or elastic-plastic mass and a gas in the cavity in the lower part of the vibration isolator and imbalance between the cone and the viscoelastic body. {Tensioning isolator and damper, foundationless, vibration isolated, dampened; Cone, viscoelastic; tension; Natural frequency; Friction; Spring property; Liquid; Gas}

Description

For this 2 pages drawings

Field of application of the invention

The invention relates to the fundamental vibration-isolated and-damped installation of machinery and equipment. In particular, machines and systems with predominantly horizontally acting vibrations can be set up vibration-insulated and damped with these tensioning vibration isolators and dampers according to the invention. The elastic erection of mainly high-level machines and systems as well as of machines and systems with load-variable center of gravity is also possible with these vibration isolators and dampers.

In steel construction, they can also be used as a connecting link between the basic framework and foundation body as well as in scaffold joints.

Characteristics of the known prior art

In practice known and widely used are rubber-based and rubber-based vibration-proof supporting supports, the so-called "vibration isolators", which provide vibration isolation in one direction almost exclusively on machines and systems Also known are vibration isolators, the conical widening and / or tapered annular Gummor elastomer body as part of a rubber-metal compound both vertical and horizontal and acting obliquely to the earth level machine vibrations and These vibration isolators are due to their relatively large spring travel for vibration isolation of tilting or torsional vibrations, such as those in slender machines with high above the bearing surfaces d he machine-related priorities are to register with top-heavy functional parts, unsuitable.

All known Schwingungdf olatoren on rubber and polyurethane base have a load-dependent natural frequency behavior. Each load case corresponds exactly to a natural frequency, the resonance range in the vicinity of this natural frequency in rubber-based vibration isolators is still relatively large compared to polyurethane-based vibration isolators. A static and dynamic. Focusing of machines and attachments on vibration isolators, d. h., a predominantly uniform load on the vibration isolators among the machines and systems is only possible in a few cases. Due to the uneven load of the vibration isolators, the resonance range under the machine or under the system increases significantly. Thus, in spite of the calculation and the associated selection of vibration isolators for new installations of machines and plants, unexpected resonance oscillations occur between the excitation and natural frequencies of the machines and systems.

Object of the invention

The object of the invention is to develop a universally applicable vibration isolator, which reduces and dampens machine impacts and vibrations, in particular and from almost all directions of the machine or system,

Explanation of the essence of the invention

The invention has for its object to develop a simple, universally applicable vibration isolator and damper for the fundamental vibration-oriented and-damped installation of machinery and equipment. According to the invention, the object is achieved in that a cone or a pressure piece with screw-on or attachable leveling used to accommodate the machine anchor bolt in a viscoelastic body up to ⁹ Ao its outer shell length and vorverspanntwertüber a Verspanneinrichtung manually. Derviscoelastic body Is embedded in a tube with or without base. To achieve an approximately uniform load distribution of the machine anchor bolt on the cone or on the pressure piece and the viscoelastic body on the base plate within the viscoelastic body enclosing pipe section or on the foundation body and to increase the Lasioinpfindlichkeit and vibration isolation is located in the cavity in the lower part the vibration isolator and damper between cone and thrust piece, viscoelastic body and base plate or between cone or pressure piece and viscoelastic body a viscous liquid. The spring stiffness and the natural frequency behavior of the Verspannschwingungsisolators and damper is by a manual clamping device, for example, from above on the pipe section with viscoelastic body and cone or pressure piece attachable and screwed with this Verspanndeckel with central bore for frictionless implementation of the cone or pressure piece screwed or attachable leveling part of the Verspannschwingungsisolators and damper changeable. This makes it possible to avoid resonance frequencies between the machine and the Veripannschwingungs isolators and dampers and between the exciter and natural frequency of the machine by simply manually tightening the cone or the pressure piece in the viscoelastic body during operation of the machine or system.

Another advantage of this Verspannschwingungsisolatoren and damper is that the vibrations of the machine or the system during operation can be kept within acceptable limits by a large pre-tension or tension of the functional parts of the Verspannschwingungsisolatoren and damper. The choice of the Shore hardness of the viscoelastic base and oscillating body is crucial for the size of the natural frequency of the unstressed and braced Verspannschwingungsisolators and damper. For example, in the case of torsional vibration isolators and shock absorbers with a high Shore hardness of the viscoelastic bodies, almost every setup from hard-elastic to conventional foundation installation is possible. Small natural frequencies are achieved with gas or fluid-filled viscoelastic bodies.

An improvement in the vibration isolation effect of these tensioning vibration isolators and dampers is also achieved with cams and / or lugs on the outer surface of the viscoelastic body. To increase the stability of the machine, the Vespannschwingungs isolators and dampers are attached to the, located with holes outside the metallic shell body parts of the base plates with anchor bolts or expansion dowels before installation of the machine on the foundation body. Tilting, slipping or wandering of the machine or the system is thus excluded from the outset.

Due to the vibrations during operation of the machine or the system, the cone of the Verspannschwingungsisolators and damper is moved to a, the pre-tension or the weight of the machine or the system corresponding equilibrium position in the viscoelastic body up and down. The dynamic load portion during the bracing phase is thereby intercepted by the back pressure of the fluid between the cone and the viscoelastic body and by the frictional force between the contact surfaces of the cone and the viscoelastic body. The

The size of the force components depends on the geometric dimensions of the cone and the viscoelastic body, the angle of inclination of the contact surfaces of the cone and the viscoelastic body relative to the vertical and the coefficient of friction of the friction pair of materials of the cone and the viscoelastic body at the contact surface. To ensure a spring and Reibweges the cone in millimeter size, the inclination angle of the contact jacket surfaces should be compared to the vertical as small as possible. For approximately uniform load distribution between the fluid pressure and the frictional force, the coefficient of friction μ between the cone and the viscoelastic body should be less than or equal to 0.5. With coefficients of friction μ greater than 0.5, this can also be achieved by a, compared to the tilt angle! the lateral surface of the cone slightly smaller angle of inclination of the lateral surface of the viscoelastic body can be achieved. With dynamic loading of the cone, a liquid gap will then form in the lower part between cone and viscoelastic body. The design of the contours of the cone and the viscoelastic body can be varied.

Ausführungsbelsplel The invention will be described below with reference to exemplary embodiments.

1 is a partial sectional view of a Verspannschwingungsisolators invention and damper Fig. 2 u. 3: partial sectional views of simplified embodiments

In Fig. 1 the structure of a Verspannschwingungsisolators and shock absorber according to the invention is shown schematically in partial section.

In a viscoelastic body 1, which is located in an upwardly open metallic housing 2 with base plate 3, a metallic cone 4 is fitted with leveling device 5 in a wedge shape. For clamping this cone 4 in the viscoelastic base body 1 is located above the cone 4 and outside of the leveling device 5, with the housing 2 by means of Spezialschlüssoln screwed cover 6. Between cover 6 and ring surface of the cone 4 are located for vibration and sound insulation and To reduce the coefficient of friction during clamping, a perforated disc 7 made of viscoelastic material and a metal disc 8. Enclosed between the recess 4 with a cavity in the lower part, the viscoelastic base body 1 and the base plate 3 is a viscous liquid 9 and a gas 10. The leveling device 5 runs in the upper part with a square out. With the aid of a square wrench, the height of this tensioning vibration isolator and damper can be adjusted by screwing the leveling device 5 in the cone 4. The attachment of this invention according to Verspannschwingungsisolators and shock absorbers on the foundation body is possible by screwing the bore provided with base plate 3 outside the housing 2 by means of anchor bolts and / or expansion dowels.

When setting up the machine or installation on these tensioning vibration isolators and dampers according to the invention, an equilibrium state between the weight of the machine or the installation and the tension of these elements and the frictional forces between the cones 4 and the viscoelastic basic bodies 1 and the resulting forces of the Backpressures of the fluids 9 and gases 10 below the cones 4 ein.Bei operation of the machine or the system, the dynamic disturbance and excitation forces in the form of the natural vibration of the machine or the system of the reaction forces in the Verspannschwingungsisolatoren and shock absorbers, the frictional forces between the Konen 4 and the viscoelastic bodies 1 and the resulting forces from the back pressures of the liquids 9 and gases 10 below the cones 4 almost perfectly insulated and damped by the static equilibrium position. FIGS. 2 and 3 show, in partial sections, schematic tension-type isolators and damper elements which can be braced exclusively by weight loading. They are particularly suitable as machine feet under machines and systems with, to the dead weights of low interference and excitation forces of machines and equipment. Compared to the Verspannschwingungsisolator and damper shown in Fig. 1, they differ in that both the base plate 3 and the additional manual clamping device is missing. The leveling device 5 is inserted into the cone 4 to match the play. By screwing the machine anchor bolt in the leveling a height adjustment of the Verspannschwingungsisolators and shock absorbers is achieved. In FIGS. 2 and 3, a pressure plate 11 made of steel is inserted underneath the leveling device 5 for the uniform load distribution of the machine or system part load on the entire bore surface in the head part of the cone 4. Instead of the viscous liquid 9 and the gas 10 in Fig. 1 is located in the cavity in the lower part of the Verspannschwingungsisolators and damper between cone 4 and viscoelastic body 1 in Figure 3.

Claims (6)

1. Tensioning vibration isolator and damper for vibration-isolated and damped baseless installation of machinery and equipment, consisting of a cone or pressure piece with leveling, viscoelastic body and tube piece with or without bottom plate or base plate, wherein the viscoelastic body in the tube piece with the outer Enclosed surface is positively embedded, characterized in that the cone or the pressure piece (4) up to ⁹ / io its lateral surface is positively inserted into the viscoelastic body (1) and, with the help of loads and / or an additional bracing this before and after the installation of the machine or system on this invention Verspannschwingungsisolator and damper in the viscoelastic body (1) can be further braced, which changes the natural frequency behavior of this Verspannschwingungsisolators and damper. 2. Verspannschwingungsisolator and damper according to claim 1, characterized in that to improve the vibration isolation in the lower part of the Verspannschwingungsisolators and damper between the cone or pressure piece (4) and the viscoelastic base body (1) a viscous liquid (9) and / or elastic and / or hard-elastic granular mass (12) is located. 3. Verspannschwingungsisolator and damper according to claim 1 and 2, characterized in that to increase the spring action of this invention Verspannschwingungsisolatoren and damper in a bore in the lower part of the cone or pressure piece (4) between the cone or pressure piece (4). and the viscous liquid (9) is a gas (10). 4. Verspannschwingungsisolator and damper according to claim 1,2 and 3, characterized in that to Ve'besserung the Schwingungsisolierwirkung and -dämpfung the inclination angle of the contact jacket surfaces of the cone or pressure piece (4) and the viscoelastic body (1) relative to the vertical as possible small, d. H. if possible, less than 10 °. Of this, in particular, the size of the spring and damping travel of the cone or pressure piece (4) in the viscoelastic body (1) depends. 5. Verspannschwingungsisolator and damper according to claim 1,2,3 and 4, characterized in that to increase the reaction force portion of the back pressure of the liquid (9) and the gas (10) against the frictional force between the cone or pressure piece (4) and the viscoelastic body (1) of the angle of inclination of the contact surface of the viscoelastif chen body (1) to the vertical relative to the cone or pressure piece (4) is to be kept slightly smaller. Thus, in the case of load surges, a liquid gap is formed in the lower part thereof between the cone or thrust piece (4) and the viscoelastic body (1) on the tensioning isolator and damper according to the invention. 6. Verspannschwingungsisolator and damper according to claim 1,2,3,4 and 5, characterized in that instead of or in addition to the liquid in the lower part of the Verspannschwingungsisolators and damper between the cone or pressure piece (4) and viscoelastic body (1) Other materials and body, such as pneumatic, hydraulic, elastic-plastic u. a. Body are located.