RU71392U1 - PLATFORM FOR PROTECTION AGAINST SHOCK AND VIBRATION - Google Patents

Abstract

The utility model relates to the field of mechanical engineering and is intended to protect objects from dynamic effects transmitted through the base in any planes. It can be used to protect against shock and vibration in REA, racks, consoles and other objects during their transportation and work on the go. The platform for protecting objects from vibrations and high-impact shocks consists of a rectangular frame with a platform hanging inside on the ropes to protect the object. The cables themselves are passed through the bushings on the frame and the platform parallel to the sides in such a way that they create four vertically oriented contours using segments on the outer side of the frame, in the case of which, in the case of vibration protection, springs are located located on the upper part of the platform (under the platform), and in the case of shock protection springs are included in the gap of the cable loop in the lower part of the platform. This ensures effective damping of impact energy due to "dry" friction in the bushings and segments. At the same time, the lower part of the cable loop performs the task of emergency limitation on impacts exceeding permissible norms.

Description

The utility model relates to the field of mechanical engineering and is intended to protect objects from dynamic effects transmitted through the base in any planes.

The utility model can be used to protect against shock and vibration of electronic equipment, racks, consoles and other objects operating during movement, as well as during transportation.

The closest prototype of the proposed platform for protection against shock and vibration is a vibration protection platform designed in conjunction with the air-mini-drill rig based on SKV-2NP, consisting of a base and a base plate connected by vibration isolators, which are elastic elements made from pieces of steel rope. Each pair of vibration isolators with a total intermediate mass is installed relative to another pair at an angle β. The intermediate masses themselves are made at different levels and do not touch. This arrangement creates stability of the base plate in the horizontal plane and provides parallel movement of the base plate relative to the base.

However, due to the circular flexibility of the elastic elements, spatial vibration isolation is provided [1].

The vibration-proof pad is designed to be isolated from vibrations and cannot, due to the small “stroke” of the pad, provide effective protection against shock of large amplitude and duration transmitted through the base in vertical and horizontal planes.

The technical result of the proposed platform for protection against shock and vibration is an increased degree of spatial protection of objects from exposure to powerful low-frequency vibrations and alternating impact effects (single and multiple) large

amplitudes and durations transmitted through the base in different planes, including seismic effects. The specified technical result is achieved due to the fact that the platform for protection against shock and vibration, consisting of a rectangular outer frame with a rectangular platform hung from inside it on a rectangular platform with a protected object, is made in such a way that the cables passed inside the platform along the sides, then through the bushings on the sides of the outer frame and through the vertical fixed segments located on the outside, are introduced into the platform, i.e. in the lower part, a vertical contour is formed, into the gap of which, in the case of vibration protection, a spring located under the platform is switched on. In the case of protection of the object from high energy impacts, the spring is included in the gap in the lower part of the circuit, while the lower part of the circuits in all cases performs the task of an emergency limiter - damper when the amplitude of the vertical deviation of the site exceeds the permissible norms.

Figure 1 shows a diagram of a platform for protection against shock and vibration. The outer rectangular frame of a given height 1 with a rectangular platform 3 hung inside it on the cables 2, on which the protected object is mounted, contains pairs of cables stretched along the sides, which are connected through the bushings 4 to segments 5, which are fixed vertically on the outside of the outer frame. Then these cables encompassing segments, are wound through bushings, into the outer frame, forming a cable vertically oriented contour, into the gap of which springs are installed, located at the ends of the contour in the upper or bottom of the platform.

In cases where a spring is installed in the upper part under the platform (Fig. 2) during vertical dynamic action in the form of vibration (for example, during transportation), this force acts directly on the spring through segments of cables adjacent to this spring. In this segment

this cable, lying outside the outer frame and wound up without breaks through the bushings and segments in the lower part of the outer platform, and does not participate as vibration protection. Thus, the elastic damping properties during vibrations are determined by the characteristics of the springs and the dissipation of the cables in the bushings.

Since, in most cases, when vibrations are not observed, a significant amplitude of deviation from the static position of the platform (except for resonance) is not observed, this solution, taking into account the high damping properties and the absence of resonance zones in the cables, provides the required vibration protection characteristics. The selection of springs and cables is carried out in accordance with the weight and size characteristics of the objects and the required vibration protection parameters.

In case of the need for effective protection against high energy impacts (including seismic impacts), the option of fixing the ends of the cable to the spring in the lower part of the platform, Fig. 3, is used. At the same time, the cable in the upper part (under the platform) has no gaps, or tension limiters are placed on the upper part, which allow connecting the lower springs.

In this embodiment, the so-called “Euler friction” is used, which occurs when the cable covers fixed arcuate surfaces. In this case, due to the strong friction of the cables against these surfaces, powerful damping occurs, which is used to dampen the energy of shock pulses of high levels.

In addition to the above, the cables located in the lower part of the platform are simultaneously emergency limiters of the amplitudes of the vertical displacements of the platform, exceeding the permissible norms. In both cases, the dimensions of the platform are saved in any version.

[1] V.F. Gorbunov I.G. Reznikov “Cable vibration isolators” Novosibirsk “Publishing house. Science »Siberian Branch of 1988

Claims (1)

A platform for protection against shock and vibration, consisting of a rectangular outer frame with a platform with a protected object posted on it inside the cables, characterized in that it is made in such a way that the cables passed inside the platform along the sides, then through the bushings on the side walls of the external platform the frames and through the segments vertically located on the outside are introduced into the platform, i.e. the lower part is formed, thereby forming a vertical circuit, in the gap of which, in the case of vibration protection, a spring is installed in its upper part located under the platform, or in the gap in the lower part of the circuit in case of protection against high energy impacts, while the lower part of the circuits in all In cases, it fulfills the task of an emergency limiter - a damper with a vertical deviation of the site above permissible norms.