RU55909U1 - VIBRATION EXTINGUISHING DEVICE - Google Patents

Abstract

The proposed utility model relates to means of protecting objects from vibration and shock and can be used in the field of power engineering as a shock absorber for power units and drives of technological equipment, including in earthquake-prone areas of location. To solve the problem of increasing the efficiency of protection against vibrations and shocks, simplifying the design solution and increasing the manufacturability and reliability of the device, a design is proposed that contains two supporting platforms: the upper and lower, parallel to one another, equipped with coaxial holes and interconnected by elastic elements in the form coil springs installed using boss type guides that are rigidly fixed to supporting platforms. Support pads are rigidly connected: the upper one is with the unit frame, and the lower one is with the mounting surface. In the coaxial holes of the support pads, there is a support sleeve with a bolt that is mounted to move in the support sleeve along the vertical axis, while the lower end of the support sleeve is rigidly fixed on the lower support platform, and a removable flange is placed on the upper end of the support sleeve. The device provides vibration protection - in the vertical plane due to the deflection of the springs, in the horizontal - due to the shift of the springs within the gap between the supporting sleeve and the base of the upper supporting platform covering it; damping and restriction of movement of the electrical unit during seismic impacts; the exception of the movement of the unit during its transportation as part of technological complexes. Positive experience has been gained from the transportation and operation of equipment with these devices in the seismically active zone on Sakhalin Island.

Description

The proposed utility model relates to means of protecting objects from vibration and shock and can be used in the field of power engineering as a shock absorber for power units and drives of technological equipment, for example, container or block-container execution, as well as for stationary equipment in earthquake-prone areas of location.

Known devices that are located between the vibroactive unit or machine and the supporting structure to reduce vibration disturbances that occur during operation of the unit.

So, for example, in the shock absorber according to the patent of the Russian Federation for invention No. 2044192 C1, prior, from 08.07.1992, MKI F 16 F 13/00, publ. 09/20/1995, designed to damp vibrations of mechanisms mounted on passenger cars, under the influence of vertical or horizontal load, the hollow elastic element is deformed. As a result, most of the energy will be redeemed and transformed into the environment. In both cases, the material of the elastic element squeezed out due to deformation fills the cavities in the shock absorber body, and the elastic element together with the vibration-insulated object moves in the direction of the force.

A disadvantage of the known shock absorber, despite the complexity of the mating structural elements and the execution of elastic elements from plastic material, is the low protection against the action of horizontal forces that arise when the train brakes sharply, when moving along curved sections of the track, etc. In addition, under intense load in severe operating conditions (sudden changes in temperature, moisture, dirt, etc. exposure), the contacting elements wear out quickly, which leads to the need for frequent adjustment and replacement.

Known shock absorber for vibroactive equipment of vehicles according to the patent of the Russian Federation for utility model No. 13075 U1 from 08.25.1999, MKI F 16 F 7/14, op. 03/20/2000, containing a metal elastic element of parallel multilayer self-sealing rings and two pairs of metal support plates that enclose and fix the elastic element and are attached to the equipment and foundation. The design of this shock absorber is also poorly protected from the effects of horizontal loads and it does not provide for the fixation of equipment from horizontal displacements.

The listed devices consist of elastic elements for damping vibrations, elements of the supporting structure and mounting parts to the unit (machine) and the base. Mounting details to the unit are made in the form of plates, flanges, threaded bushings and rods, in which elastic elements are installed, and have the ability to move.

To ensure the transportation of vibration-insulated aggregates, for example, by rail, where overloads reach 3g, and equipment operation under conditions of possible shock loads, additional devices are used in the form of movement limiters, stretch marks, complex in shape and, as a result, low-tech structures of elastic elements ( see, for example, RF patent No. 2068512 of March 25, 1991, IPC F 16 F 3/08, publ. October 27, 1996). This complicates the support structure.

damping device and reduces the ability to use units.

Closest to the proposed solution for the totality of features is the annular shock absorber according to the patent of the Russian Federation for utility model No. 24865 U1 dated 04.02.2002, MKI F 16 F 7/14, publ. 08/27/2002, adopted as a prototype.

The prototype consists of two supporting platforms - the upper and lower, which are parallel to one another relative to the vertical axis, are interconnected by flexible metal rods and springs, and the lower platform, consisting of two disks, can be rotated in the horizontal plane. At the same time, the design of the bearing pads and the combination of the elastic elements of the shock absorber-prototype in the best way dampens the vibration of the machine.

However, in the prototype, due to the presence of a large gap between the upper support platform and the spring, as well as due to the elastic properties of the flexible rods covering the support sites:

- not provided for fixing the unit (machine) relative to the mounting surface during transportation;

- limited protection against overloads arising from shock during transportation, seismic and explosive impacts;

- there are no restrictions on displacements in both horizontal and vertical planes arising from large inclinations of the structure and when exposed to linear accelerations.

Low and manufacturability of the design of the prototype due to the presence of curved flexible rods located at a given angle with respect to the reference areas.

These features narrow the scope of the prototype shock absorber, excluding, in particular, the possibility of using transportation of aggregates and equipment by rail, where accelerations reach 3g, and their placement in earthquake-prone areas. In these

conditions, the effectiveness of vibration protection when using a shock absorber prototype is relatively low.

The objective of the proposed solution is to increase the efficiency of protection against vibration and shock, simplifying the design and increasing the manufacturability and reliability of the vibration damping device.

To solve the problem in a device for damping vibrations, containing two bearing pads: the upper and lower, which are parallel to one another, are provided with coaxial holes in the center and interconnected by elastic elements, the feature is that the lower bearing pad is made with the possibility rigid connection with the mounting surface, the elastic elements are made in the form of cylindrical springs, which are fixed using guides such as bosses, rigidly fixed to the supporting platforms ah, in the coaxial holes of the support pads there is a support sleeve with a bolt that is mounted to move in the support sleeve along the vertical axis, while the lower end of the support sleeve is rigidly fixed on the lower support platform, and a removable gasket is placed on the upper end of the support sleeve.

The number of coil springs in the proposed device is not less than two and can be increased depending on the mass of the vibroactive unit.

The support sleeve may be rigidly fixed to the lower support platform by welding, or by casting, or by pressing, or by flaring, or in another way, for example, by bolting.

The support sleeve and the bolt can be provided with a mutual thread for the possibility of reducing / increasing the working stroke of the coil springs and rigid fixation of the unit on the lower supporting platform during transportation.

The removable gasket located on the upper end of the support sleeve can be made in the form of a ring and is provided with a flange on the outer diameter to provide additional fixation of the support sleeve in the hole of the upper support platform.

The proposed design of the vibration isolator is shown in figure 1.

The device contains two horizontally located supporting pads: the upper 1 and lower 2, which are provided with coaxial holes in the center. The upper platform 1 is rigidly attached to the base of the vibroactive unit, and the lower 2 is also rigidly attached to the mounting surface, which may be, for example, the bottom of the container or foundation. Along the perimeter of the coaxial holes between the support platforms are located coil springs 3, which, with the help of guides, for example, bosses 4, are rigidly fixed on the counter surfaces of the platforms 1 and 2.

A support sleeve 5 with a tie bolt 6 is installed in one axis with coaxial holes in the pads 1 and 2, which has the ability to move in the support sleeve 5 along the vertical axis due to the presence of mutual threads in these parts. The support sleeve 5 is rigidly fixed on the site 2 or by welding, or by casting, or by pressing, or by flaring, or, for example, by a bolted connection method.

Between the lower surface of the base of the unit and the upper end of the support sleeve 5, a removable gasket 7 is freely located, which is installed during the transportation of the object. The gasket 7 is equipped with a flange 8 to exclude horizontal displacement of the upper supporting platform 1. In the loaded state, there is a gap between the upper end of the sleeve 5 and the base of the unit equal to the height difference of the coil springs 3 at the working and maximum load.

Note. Here, under the working load refers to the load on the elastic element during operation of the vibroactive unit or machine, and by

maximum - when the load from the unit is added to the load from seismic or explosive impacts.

Figure 1 also shows the overall dimensions of the device.

The operation of the device is as follows.

The set of proposed vibration isolators is attached to the base of the insulated object by the upper supporting platform 1 and to the mounting surface by the lower supporting platform 2. The springs 3 are fixed by the guide bosses 4 installed counter-mounted in the supporting platforms 1 and 2.

If the equipment is mounted on the operating site, the removable gasket 7 is not installed, the bolt-tie 6 is not tightened, and a gap remains between the lower surface of the unit base and the upper end of the support sleeve 5. In this case, when a vibroactive machine, for example, a diesel generator, is operating, a set of vibration isolators significantly reduces the vibration load on the mounting surface due to the elastic properties of the coil springs 3.

When transporting container or block-container equipment, a gasket 7 is installed in the vibration isolator, the bolt-tie 6 is tightened, excluding the gap between the gasket 7 and the lower surface of the base of the unit. Thus, the proposed device turns into a rigid structure without the possibility of displacements and displacements in both horizontal and vertical directions. The elimination of movement in the horizontal plane is also facilitated by the presence of flanging on the gasket 7. At the place of operation, the gasket 7 is dismantled, the bolt 6 is installed with a gap of 0.5 ... 1.0 mm between the head of the bolt and the base of the unit.

When shocks going to the insulated unit from the installation side, for example, seismic, the proposed device compensates for shock loads due to the deflection or shift of the springs 3 and limits the movement

operating electrical unit in both planes. In the vertical plane, by the supporting sleeve 5 and the tightened bolt 6, and in the horizontal plane, by the supporting sleeve 5 and the base of the upper supporting platform covering it.

It is obvious that the proposed device design in comparison with the known without increasing complexity leads to a significant increase in the effectiveness of vibration isolation.

The inventive device provides several functions:

- vibration protection - in the vertical plane due to the deflection of the springs, in the horizontal - due to the shift of the springs within the gap between the supporting sleeve and the base of the upper supporting platform covering it;

- damping and limiting the movement of the electrical unit during seismic impacts;

- the exception of the movement of the unit during its transportation as part of technological complexes, for example, in containers.

A detachable gasket with a flange, installed between the base of the unit and the support sleeve, also performs two functions:

- when installing the unit at the place of operation, the preliminary (temporary) installation of the gasket ensures the alignment of the supporting sleeve relative to the upper supporting platform.

- during transportation, when the gasket is installed and the bolt is tightened, movements and a long maximum tightening of the springs are excluded, which removes the accumulation of fatigue stresses of the spring material associated with it (tightening). Flanging further limits horizontal displacements of the unit.

The proposed vibration protection device is as simple as possible to manufacture, install and adjust and does not require the use of special and scarce parts, assemblies and materials. All structural parts of the device can be manufactured on standard equipment with standard

technological processes and without additional equipment, which indicates a high level of manufacturability and reliability of the proposed solution compared to analogues.

As the main structural material, steel with protective coatings can be used.

The use of the claimed device in any vibration-insulated objects does not require the installation of additional safety devices and other fixing elements.

The proposed changes, additions and improvements to the design of the vibration damping device contribute to the solution of the task of increasing the efficiency of protection against vibration and shock, simplifying the design and increasing the manufacturability and reliability of the device as a whole.

The proposed device is implemented on a diesel power unit weighing 14,700 kg. The vibration protection kit consists of eight damping devices with six springs in each. Positive experience has been gained from the transportation and operation of twelve block-container diesel power plants in the seismically active zone on Sakhalin Island.

Claims (5)

1. A device for damping vibrations, comprising two supporting platforms: the upper and lower, parallel to one another, equipped with coaxial holes and interconnected by elastic elements, characterized in that the lower supporting platform is made with the possibility of rigid connection with the mounting surface, elastic elements made in the form of cylindrical springs with the possibility of interaction with guides such as bosses, rigidly fixed on the supporting platforms, located in the coaxial holes of the supporting platforms the supporting sleeve with a bolt that is mounted to move in the supporting sleeve along the vertical axis, the lower end of the supporting sleeve is rigidly fixed to the lower supporting platform, and a removable gasket is placed on the upper end of the supporting sleeve. 2. The device for damping vibrations according to claim 1, characterized in that the number of coil springs is at least two. 3. The device for damping vibrations according to claim 1 or 2, characterized in that the supporting sleeve is installed on the lower supporting platform either by welding, or by casting, or by pressing, or by flaring, or, for example, a bolted connection. 4. The device for damping vibrations according to claim 1, characterized in that the supporting sleeve and the bolt are provided with a mutual thread. 5. The device for damping vibrations according to claim 1, characterized in that the gasket is made in the form of a ring and is equipped with a flange.