RU168312U1 - COMPRESSIBLE ELASTIC SPRING - Google Patents

Abstract

The invention relates to compressible polymer springs designed to absorb, dissipate and return energy during operation from a dynamic shock load applied to a spring created by shock and / or vibration, for example, in nodes of an absorbing apparatus of a passenger or freight railway car. A compressible elastic spring consists of polymer elastic elements, between which separation plates with receiving through holes are placed, each elastic element has a pair of end surfaces. On the end surface of the elastic elements there are protrusions made as a single unit with the elastic element and entering into the through receiving holes of the separation plate. The protrusions on the element are evenly spaced along the end surface and radially offset from the protrusions of the second end surface by at least 15 ° and their number coincides with the number of protrusions of the second end surface and is at least 3 pcs. on each of the end surfaces. The peripheral end of the upper part of the protrusion is made inclined to ensure insertion into the through hole of the plate during compression of the elastic element. The protrusions on the element, on which the separation plates with receiving holes are installed, in cross section have overall dimensions of at least D / 25, where D is the diameter of the elastic elements of which the spring consists. The technical result is to increase the reliability and energy intensity of the spring. 4 s.p. f-ly, 2 ill.

Description

The utility model is used in various fields and relates to mechanical engineering, in particular to compressible polymer springs, having a new layout for centering and fastening the polymer elements that make up the spring, designed to absorb, dissipate and return energy during operation from the dynamic shock load applied to a compressible spring created by shock and / or vibration. For example, a polymer spring is widely used as an integral part of the absorbing unit assembly of a passenger or freight railway car.

A known design of an absorbing apparatus (patent RU No. 136776, B61G 9/14, September 6, 2013), comprising a rectangular plate, a coupling bolt passing through a central hole in the plate, six polymer elastic elements made of Heitrel thermoplastic elastomer, made with the possibility of energy dissipation due to internal friction during elastic deformation of polymer elastic elements, each of the polymer elastic elements has a toroidal shape, spacers are installed between them, each of which has a central hole, with the help of which ostavki mounted on the clamping bolt is movable along its axis, the edges of the block polymer elastic members installed on one spacer. Spacers are made in the form of a flat disk having punching holes with protrusions directed to opposite sides of the disk planes, protrusions are embedded in polymer elastic elements, spacers mounted on the edges of the block of polymer elastic elements are made with protrusions directed towards the extreme polymer elastic element.

Known compressible elastomeric spring (patent RU No. 2491197, B61G 9/06, 01.05. 2008), containing many elastomeric gaskets and separating plate elements located between them, arranged coaxially and sequentially one after another and forming a multi-tiered package. Each elastomeric gasket has a side surface and a pair of end surfaces located normal to the central axis. The dividing plate element has first and second flat surfaces and an axial hole. In a compressible spring according to the first embodiment, a plurality of teeth are made on each side of the dividing plate element near the edge of the axial hole. The teeth have a trapezoidal shape and extend outward at an angle relative to a flat surface into the material of the corresponding elastomeric gasket. In the compressible spring according to the second embodiment, near the peripheral edge of the axial hole there is a means for attaching the separation plate element to the elastomeric gasket. It is possible to absorb impact energy without using a metal rod or body as a guide.

Known elastomeric spring for a railway carriage (patent RU No. 2510702, F16F 1/40, B61G 9/06, 09/03/2009) containing a spring element and two metal plates. The spring element is obtained from a blank of thermoplastic polyester elastomer. The workpiece has a cylindrical shape and is made with an axial hole. Metal plates are adapted for attachment to the ends of the workpiece. Each plate is made with a through hole in the center, has a figured peripheral contour and contains many mechanical fasteners radially remote from the center. The fasteners are made integrally with the plate, are perpendicular to its surface and have a tooth emerging from the side of the fastener. In the spring, according to the second embodiment, the fasteners have main surfaces located perpendicular to the line dividing each plate into symmetrical halves. In the spring according to the third embodiment, the fasteners have main surfaces parallel to the line dividing each plate into symmetrical halves. This improves the reliability of the connection of the spring element with the plates, as well as preventing excessive radial expansion of the spring element during compression.

Any of the above prototypes provides fixing and / or centering of the polymer elements of a compressible elastic spring. However, well-known solutions require punching holes with protrusions that are embedded in polymer elastic elements; dividing plate elements with teeth embedded in polymer elastic elements, and / or pre-axial compression of the preform from thermoplastic polyester elastomer and metal fasteners, thereby violating the continuity of the polymer elastic elements and / or preventing the possibility of manufacturing polymer elastic elements separately from metal fasteners.

Thus, there is a need and a need for polymer elastic springs having a new arrangement for centering and fastening, designed to absorb, dissipate and return energy during operation from a dynamic shock load applied to a compressible spring securely connected to a pair of metal plates without breaking the continuity and / or the possibility of manufacturing separately from metal fasteners polymer elastic elements and preventing radial expansion beyond a predetermined limit in axial compression of the spring.

The objective of the utility model is to obtain a technical result for increasing energy intensity, reliability, safety and performance of a compressible elastic spring.

This problem is solved in that a compressible elastic spring, consisting of polymer elastic elements, between which separation plates with receiving through holes are placed, each elastic element has a pair of end surfaces, characterized in that there are protrusions on the end surface of the elastic elements as a whole with an elastic element and entering into the through receiving holes of the separation plate.

The protrusions on the element are evenly spaced along the end surface and radially offset from the protrusions of the second end surface by at least 15 °, their number coincides with the number of protrusions of the second end surface and is at least 3 pcs. on each of the end surfaces.

The peripheral end of the upper part of the protrusion is made inclined to ensure the insertion of a separation plate into the through hole during compression of the elastic element, which allows filling the plate hole due to elastic deformation, increasing the reliability of the connection of polymer elements with the separation plates. The protrusions on the element, on which the separation plates with receiving holes are installed, in the cross section have overall dimensions of at least D / 25, where D is the diameter of the elastic elements of which the spring consists.

According to the utility model, a compressible elastic polymer spring is created for absorbing, dissipating and returning energy from a dynamic shock load applied to a compressible spring, preventing excessive elastic deformation in the radial direction beyond specified limits under axial compression, increasing rigidity, and therefore, energy intensity, initial force compression and reliability of the connection of elements with plates.

The optimal size of the protrusions and their number are determined calculated and empirically depending on the parameters of the given power characteristics for the given values of the stroke, energy intensity, preliminary preload and compression force.

The essence of the utility model is illustrated in FIG. 1 is a longitudinal section through a compressible polymer spring; FIG. 2 is a top view of one elastic element without a dividing plate.

Compressible elastic spring consists of polymer elastic elements 1, between which separation plates 2 with receiving through holes 3 are placed. On the end surface of the elastic element 1 there are protrusions 4. The protrusions 4 are made integrally with the elastic element 1 and have an inclined peripheral end of the upper part for ensuring the introduction into the receiving through holes 3 of the separation plate 2. The peripheral end of the upper part of the protrusion 4 allows you to fill the hole 3 of the plate 2 during compression of the elastic element 1. an increase in the reliability of the connection of the polymer elements 1 with the dividing plates 2, as well as the prevention of excessive elastic deformation in the radial direction over predetermined limits during axial compression, an increase in the rigidity, and hence the energy intensity, and the initial compression force of the elastic elements 1, are triggered.

At present, design documentation has been developed for this design, according to which prototypes undergoing comprehensive tests have been manufactured.

Claims (5)

1. Compressible elastic spring, consisting of polymer elastic elements, between which separation plates with receiving through holes are placed, each elastic element has a pair of end surfaces, characterized in that on the end surface of the elastic elements there are protrusions made as a whole with the elastic element and entering the through receiving holes of the separation plate. 2. Compressible elastic spring according to claim 1, characterized in that the protrusions on the element are evenly spaced along the end surface and radially offset from the protrusions of the second end surface by at least 15 °. 3. Compressible elastic spring according to claim 1, characterized in that the protrusions on the element are arranged uniformly along the end surface, their number coincides with the number of protrusions of the second end surface and is at least 3 pcs. on each of the end surfaces. 4. Compressible elastic spring according to claim 1, characterized in that the peripheral end of the upper part of the protrusion is made inclined to provide insertion into the through hole of the separation plate during compression of the elastic element, which allows filling the hole of the plate due to elastic deformation, increasing the reliability of the connection of polymer elements with separation plates. 5. A compressible elastic spring according to claim 1 is characterized in that the protrusions on the element onto which the separation plates with receiving holes are mounted have a cross-sectional dimension of at least D / 25, where D is the diameter of the elastic elements that make up the spring.

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