RU2626787C2 - Vibration isolator "double bell" (versions) and method of manufacturing of its elastic hysteresis elements from wire material - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: vibration isolator contains two bell-shaped elastic-hysteresis elements made by cold pressing method from the wire material, on which bolts are fastened with the help of washers and nuts. The shockproof cushion of the metal-rubber is fixed on the head of one of the bolts. The support base is made in form of a cylindrical flange, smoothly turning into a conical part. Bell-shaped elements are connected to each other along the periphery of the bases. The connection according to the first variant is made by a compression coil spring, a coil of one or three wires, or by two springs screwed together. The connection according to the second variant is made by three compression springs: two conical ones with high compliance and a cylindrical one with greater rigidity. Conical coil springs are made from one wire, and cylindrical one - from one, two or three wires. A workpiece is made from a grid, formed in form of a stocking, woven from wire spirals. The axes of the coil are located parallely to the generating grid. One part of the grids is weaved from the spirals of the right whorl, and the other part - from the spirals of the left whorl. A continuous strip is formed from the layer of the right whorl and the layer of the left whorl. The coils are inserted into curls of coils of one layer in the coils of the other layer along the entire length of the strip without compression of the curls of the coils. A workpiece is formed from the obtained strip. In each layer of the continuous strip grids are laid end to end. Joints in different layers are evenly distributed over the circle. The ends of the strip are located against each other in one radial section of the workpiece. There is the same number of stratum layers in each radial section.

EFFECT: simplification of design, possibility of automating the assembly process.

13 cl, 12 dwg

Description

The invention relates to all-metal vibration isolators with an elastic hysteresis element made of wire material, capable of operating in an aggressive environment, in conditions of radiation, open space and elevated temperature (up to 500 ° C).

Known vibration isolators of the DKU type (“double bell reinforced”) (Lazutkin GV Improving the designs and methods for calculating vibration isolators based on wire fiber material / GV Lazutkin, VA Antipov, AL Ryabkov. - Samara: Samara State University of Railways. 2008. - 200 p.), Currently used for the suspension of devices installed on spacecraft.

These vibration isolators are made in the form of two bell-shaped elements - “bells” made by cold pressing from MP wire material (metal rubber) reinforced with a wire bundle wrapped with a stretched wire spiral, mounted on top of each other, rigidly fastened around the periphery by steel wire stitching. Bolts are fixed on the bells, an shockproof pillow made of MP material can be fixed on one of the bolts. Bolt mounted profiled restriction washers and nuts.

These vibration isolators in the class of all-metal vibration isolators of low load capacity (up to 1000 N), in our opinion, currently have the best vibration isolating, shockproof and strength characteristics.

The disadvantage of these vibration isolators is the great difficulty in developing their automated manufacturing. Currently, the manufacture of these vibration isolators requires a large amount of manual labor. The disadvantages of this vibration isolator include the complexity of its design and the high cost of the vibration isolator.

The most labor-intensive technological operations in the manufacture of this vibration isolator, which takes up the bulk of the manual labor, are the formation of blanks from MP wire material, the manufacture of a reinforcing bundle and the reinforcing of these blanks, the stitching of its elastic-hysteresis elements (UGE) with wire.

DK vibration isolators are also known (see the same book), made in the form of two bell-shaped elements - "bells" made by cold pressing from MP wire material, mounted on top of each other with bases, rigidly fastened around the periphery by steel wire stitching. Bolts are fixed on the bells, an shockproof pillow made of MP material can be fixed on one of the bolts. Bolt mounted profiled restriction washers and nuts.

The main disadvantage of these vibration isolators is their low tensile strength. Due to this drawback, these vibration isolators are not currently used.

Vibration isolator DK in technical essence is the closest to the proposed and adopted as a prototype.

The task is to create an all-metal vibration isolator, the manufacture of which could be easily automated and produce a vibration isolator in large series with elasto-friction, shockproof and vibration-isolating properties, at least not worse than that of a DCU vibration isolator with strength properties quite sufficient for its widespread use in aircraft, land transport, chemical industry, general engineering, electronics and household appliances, with a cost that is several times lower than the cost STI manufacturing vibroinsulator DKU, and cost-effective when used in these areas of technology.

The problem is solved by the fact that the proposed vibration isolation "Double bell" containing two elastic hysteresis elements made in the form of bell-shaped elements made by cold pressing of wire material mounted on top of each other, fastened around the periphery of the bases, bolts mounted on bell-shaped elements with with the help of profiled limit washers and nuts, and a shockproof pillow made of MP material, "Metal rubber", mounted on the head of one of the bolts, excellent which consists in the fact that the elastic hysteresis elements are made of stockings made of a mesh woven from wire spirals of the right twist, stretched to a step t determined from the range of values D <t≤D + d, where D is the diameter of the spiral, d is the diameter of the wire, and a stocking made of a mesh woven from spirals with the same parameters but of the left twist, and in the body of each elastic-hysteresis element, the layers formed by the turn of the stocking with spirals of the right twist alternate with the layers formed by the coil of the stocking with spirals of the left twist, and the support the base of each bell is made in the form of a cylindrical flange smoothly passing into the conical part of the bell-shaped element, and both of these elements are fastened to each other by a spiral compression spring, twisted from one or three wires, or by two springs screwed together, between the coils of the cylindrical part of the spring or springs and the cylindrical outer surface of the support base of each bell-shaped element has a concentric gap, the size of which is the smallest possible, but such that it provides a free increase in the outer diameter of the bases of these elements during working compression deformations along the axis of the vibration isolator, and support coils - one or two at each end of the spring, or coil coils twisted close to each other and protruding from the screwed part, are deformed in radial directions and bent into cylindrical flanges of bell-shaped elements in such a way that these elements are pressed against each other with a force distributed over the support platforms of the bases, and between each external support coil of the spring or springs By using the conical part of the bell-shaped element, the radial, concentric axis of the vibration isolator have a gap either absent or some size of this gap exists, for which the end of each of the external support coils is cut so that each external support coil of the spring after its deformation in radial directions has the shape of a circle with a center on the axis of the vibration isolator, and the sharp edges of the cut contour are rounded.

In the technical literature and documentation, it is customary to designate “Double Bell” type vibration isolators using the abbreviation reflecting the design features of the vibration isolator. For example, DK Vibration Isolator, DKA Vibration Isolator, DKU Vibration Isolator, and DKM Vibration Isolator (see the same book). In these abbreviations, DK stands for double bell, A - reinforced, U - reinforced, and M - upgraded.

According to this tradition, the proposed vibration isolator is assigned the acronym DCCHP.

The acronym DKChP stands for double bell type vibration isolator with elastic hysteresis elements made of a stocking made of wicker mesh, with the fastening of bell-shaped elements - bells - spiral compression springs.

The manufacture of bells by the following method from stockings made of woven mesh ensures their tensile strength when a tensile load is applied along the axis of the vibration isolator, since in order to break the bells, it will be necessary to break all the turns of the mesh spirals in each layer of the bell, and, therefore, wire reinforcement material reinforcing harness in this case is not necessary.

The manufacture of blanks of bells from wicker mesh provides a regular structure of the material of the bells, a uniform distribution of the density of the material in their volume. The formation of blanks of bells from alternating stockings of spirals of the right and left twists provides a strong adhesion of the coils of the spirals of the grid in adjacent layers. All this improves the strength and elastic-friction characteristics of the vibration isolator. Note that the maximum dispersion coefficient of products from wire material made of mesh with cyclic compression ψ _max = 2.5-2.6 is higher than that of products from wire material MP, for which ψ _max = 2.2-2.3 , and about the same or slightly smaller than that of products made of MP material reinforced with a wire rope wrapped in a spiral.

In addition, the stocking spirals of the proposed DKCHP vibration isolators are made of wire of a larger diameter than the spirals of the DKU vibration isolator with similar vibration isolating characteristics, which greatly reduces the manufacturing cost of the proposed vibration isolator.

The fastening of the bells with the help of a spiral compression spring makes it much easier to automate this operation (see below) than the operation of stitching the bells of the DKU vibration isolator with a wire spiral.

To ensure the required tensile strength of the proposed DKChP vibration isolator, the fastening spring is made of caged spring steel wire with a diameter greater than the diameter of the stitching wire of the bells of the DKU vibration isolator.

It should be noted that giving the external support coils of the spring a circle shape centered on the axis of the vibration isolator ensures concentricity and constancy of the gap between the external support coil and the base of the conical part of the bell. Observance of the concentricity of this gap and the gap between the supporting bases of the bells and the spring holding them together is one of the important conditions for ensuring the UVC isotropy in the circumferential direction and their uniformity in the serial batch of vibration isolators.

The radial clearance between the outer support turn and the base of the conical part of the bell, the geometry of the outline curve of the zone of smooth transition of the cylindrical flange to the conical part of the bell, the amount of force pressing the bells against each other, significantly affect the UVC of the vibration isolator and are selected experimentally.

The production of bells of the proposed vibration isolator DKChP can be fully automated (see below).

All of the above qualities of the proposed DKChP vibration isolator allow us to develop a batch production technology for this vibration isolator with a cost price that is profitable for its use even in household appliances, which solves the problem.

In addition, in order to increase the elastic-frictional characteristics (UVC) of the vibration isolator, a Double Bell vibration isolator is proposed, characterized in that the stockings are made of a prestressed mesh, in which one of each pair of contacting spirals is elastically stretched and the other elastically compressed by the same load applied along the axis of the spirals.

The use of stockings from a prestressed braided mesh improves the dissipative properties of the proposed DKChP vibration isolator by increasing the dry friction forces on the contact surfaces of the spiral coils of the mesh of each stocking and, therefore, increasing the energy dissipated by the mutual slipping of the coils of the bell material during their cyclic deformation.

In order to increase the stability of the UVC of the DKChP vibration isolators during operation, the Double Bell vibration isolator is proposed, characterized in that the pressing force of the bell-shaped elements to each other is ensured by elastic tensile deformation of the fastening spring in the direction of the axis of the vibration isolator.

When running, shrinkage and wear of the coils of the wire material of the bells occurs, due to which there is a decrease in the force of pressing the bells against each other and, consequently, the deterioration of the UVC of the vibration isolator. The creation of this force due to the elastic deformation of the fastening spring can significantly increase the operating time range in which the UVC of the vibration isolator will remain within acceptable limits.

In addition, a Double Bell vibration isolator is proposed, characterized in that one of the support turns of each end of the fastening spring is bent to the bell-shaped element flange, and the second to the smooth transition part from the flange to its conical part or to its conical part with some pressing force or with a small gap.

In order to ensure that the bells are not rotated relative to each other, the Double Bell vibration isolator is proposed, characterized in that one or two diametrically located through holes are made in the flanges of the bell-shaped element, into which clips are made, made in the form of brackets from steel wire, the ends of which are bent into radially located grooves in the flanges of bell-shaped elements flush with their outer surface.

In order to increase the load-bearing capacity of the proposed vibration isolator, two spiral compression springs are installed on its elastic hysteresis elements from the outside, having a cylindrical and conical part, twisted from one, three or more wires, screwed cylindrical parts with each other in such a way that the first turn of the cylindrical part of each springs protrudes outward from the screwed part of these springs, is deformed in radial directions and bent onto the cylindrical flange of each bell-shaped element with the same azom as coils fastening spring isolator proposed other embodiments, a tapered portion attached to the same elements uprugogisterezisnym bolts, which isolator is fastened to the vibration isolator and the object support by means of elastic washers and nuts.

Note that the use of multi-core springs (three-core or more) improves the dissipative properties of the proposed vibration isolators.

Plastic deformation in the radial directions of the first turn of the cylindrical part of each spring ensures reliable connection of the springs to each other, eliminates the possibility of partial or complete unscrewing of them during running hours.

In addition, in order to improve the UV characteristics of the proposed vibration isolators, the compression springs are designed so that after screwing the springs into each other, gaps remain between the outer ends of the elastic hysteresis elements and the response ends of the conical parts of the springs, the value of which and the parameters of the springs are selected so that the fastening of bell-shaped elements and when placing a vibration-insulated object on vibration isolators without elastic washers and nuts mounted on bolts, these gaps are completely selected either ceases certain amount of clearance, which is fully selected when attaching by means of elastic washers and nuts on the support isolator and vibroizoliruemogo object on vibration isolators.

In those cases when the simultaneous provision of reliable fastening of the bells and unloading of the UGE from the action of the weight of the vibroinsulated object attributable to the vibration isolator, when using these springs leads to an undesirable increase in the average cyclic stiffness of the vibration isolator and, therefore, to an undesirable increase in the resonant frequency of the vibration isolator, a double isolator is proposed ", Characterized in that springs are installed on the elastic hysteresis elements, the cylindrical part of which is twisted of three or more wires and the parameters of this part of the springs are selected so that the fastening of bell-shaped elements is reliable, and the conical part of the springs is made up of only one wire of each spring, and the parameters of the conical part of the springs are selected so that when installing the vibration-insulated object on the vibration isolators, they are completely or partially unloaded the elastic hysteresis element from the force of the weight of the vibration-insulated object attributable to the vibration isolator.

In this case, the conical parts of the springs will have great flexibility and the placement of such springs on a vibration isolator will not excessively increase its resonant frequency.

Vibration insulators, unloaded from the weight of the vibration-insulating object falling on the vibration isolator, significantly expand the range of deformations of UGE, where its loading processes (loading, unloading) occur without “tails” (“tail” here means the range of deformations (large deformations) of loading processes, in which, with increasing strain, the average cyclic rigidity of the UGE sharply increases and its dispersion coefficient decreases), due to which the UVC of the vibration isolator improves.

In addition, in order to ensure a longer life and greater stability of the UVC of the vibration isolator during operation, the Double Bell vibration isolator is proposed, containing two elastic hysteresis elements made in the form of bell-shaped elements made by cold pressing of wire material mounted on top of each other, fastened together on the periphery bases, bolts fixed to bell-shaped elements with profiled restrictive washers and nuts, and a shockproof pillow made of material MP, “Metal rubber”, mounted on the head of one of the bolts, characterized in that the elastic-hysteresis elements - bell-shaped elements - are made of stockings made of a mesh woven from wire spirals of the right twist, stretched to a step t, determined from the range of values D < t≤D + d, where D is the diameter of the spiral, d is the diameter of the wire, and the stocking made of a mesh woven from spirals with the same parameters, but of the left twist, and in the body of each elastic-hysteresis element, layers formed by a turn of the stocking with spirals equal strands, alternate with the layers formed by the turn of the stocking with spirals of the left strand, and the supporting base of each bell-shaped element is made in the form of a cylindrical flange smoothly passing into the conical part of this element, and are fastened by three compression springs - two conical with great flexibility, twisted from one wire, and cylindrical with greater rigidity, twisted from one, two or three wires, conical springs are dressed on bell-shaped elements to the end in their flanges, the first and last turn are cylindrical spring springs are deformed in radial directions in such a way that they fix the conical springs from unscrewing and press the support coils of the conical springs against the flanges of these elements by the force created by the elastic tensile strain of the coil spring, and the magnitude of this deformation is selected so as to prevent a gap between these coils when installed on the vibration isolator of the vibration-insulated object and the operating time of the vibration isolator, and between the ends of the elastic hysteresis elements and the counter ends of the conical springs are I have gaps, the magnitude of which and the parameters of the springs are selected in such a way that they are completely selected when a vibroinsulated object is placed on the vibration isolators and the required amount of force is created, which presses the support coils of the conical springs to the elastic hysteresis elements, and in this position the vibration isolator is attached to the vibroinsulated object and the support with elastic washers and nuts.

With a complete selection of the gaps between the ends of the conical springs and the UGE, the UGE of the vibration isolator is either completely unloaded from the weight of the vibroinsulated object attributable to the vibration isolator, or partially, but in any case, the support turns of the conical springs are pressed against the UGE sites with a force that provides such boundary conditions to the bells, at which provide good UVC to the vibration isolator.

In reference points of the UGE of the vibration isolator, in any of these cases, they are pressed with a force equal to the weight of the vibroinsulated object attributable to the vibration isolator, and, consequently, for the proposed DKChP vibration isolator with three fastening springs, either the whole force of the bells to be pressed against each other, or most of it is provided due to the elastic deformation of the conical springs and this ensures good stability of the UVC during operating hours and an increase in the life of the vibration isolator.

We also note that the heads of the mounting bolts for all of the proposed DKCHP vibration isolators are recessed in the UGE body, which ensures the greater working stroke of the vibration isolator at the same height dimensions as the DK series vibration isolators. The installation of a shockproof pillow made of MP material on one of the bolt heads improves the shockproof characteristics of the vibration isolator, but it may not be placed in cases where the twist step and the number of turns of the conical part of each spring are such that, upon impact, the spring turns are stacked on each other before the shockproof pillow will come in contact with the head of another bolt.

A known method of manufacturing UGE made in the form of bells from wire material (see AS USSR No. 1712049, IPC B21F 21/00. Eskin ID Method for the manufacture of conical elastic hysteresis elements from wire material / ID Eskin, RV Maslov. - Publ. 1992, Bull. No. 6) by crimping a workpiece that is preliminarily made from a mesh formed in the form of a stocking, woven from wire spirals stretched to a step equal to the diameter of the spiral, so that the axis of the spirals is positioned parallel to the stocking and namata wound in the form of a ball on the central rod, the diameter of which is equal to the diameter of the mounting bolt, characterized in that one part of the stocking segments are woven from right-hand spirals and the other part is from left-hand spirals; whereby one end of one segment is inserted into the other and squeezed at the junction, then placed on a stocking of spirals of the right twist, a stocking of spirals of the left twist and crimped are inserted into the spirals of one stocking in the spirals of the other stocking throughout without compressing the turns of the spirals, after which the resulting strip is wound on the rod with overlapping layers and with a maximum twist angle as close to 90 ° with respect to the axis of the rod.

This method is conveniently used for the manufacture of UGE of the proposed DKChP vibration isolators in small series, for example, for use in space technology.

But with this method, it is difficult to fully automate the operation of inserting the end of one segment of a stocking into another segment.

Therefore, the task is to develop a method of manufacturing UGE of the proposed vibration isolators DKChP, which allows to minimize the amount of manual labor in the manufacture of UGE and cost-effective for large series of production of the proposed vibration isolators.

A method of manufacturing a UGE according to A.S. USSR No. 1712049 in technical essence is closest to the proposed and adopted as a prototype.

The problem is solved in that a method is proposed for manufacturing the elastic hysteresis elements of the proposed “Double bell” vibration isolator from wire material by pressing a workpiece along the axis of the vibration isolator, which is preliminarily made from a mesh formed in the form of a stocking, woven from stretched wire spirals, so that the axis of the spirals placed parallel to the generatrix of the stocking, the mesh of one part of the stocking is woven from spirals of the right twist, and the other part from spirals of the left twist, shapes they cut a continuous strip from a layer with stockings from spirals of the right twist and a layer with stockings from spirals of the left twist and squeeze the coils of one layer into the spirals of another layer along the entire length of the strip without compression of the coils of spirals, and a blank is formed from the obtained strip, characterized in that the stockings are woven from spirals stretched to a step t determined from the range of values D <t≤D + d, where D is the diameter of the spiral, d is the diameter of the wire, and in each layer of a continuous strip, the stockings are laid butt to each other, and the joints of the stockings are different layers carry each other each other so that in the volume of the workpiece they are approximately evenly distributed around the circumference and the length of the strip is such that after the required number of turns of the strip is completed, its ends are located in the same radial section of the workpiece against each other and, therefore, in each radial section of the elastic hysteresis element the same number of layers of a continuous strip were located.

In the proposed method, the operation of inserting the end of one stocking into another is excluded. Performing other operations of the proposed method can be automated without much difficulty. This solves the problem.

In addition, a method for manufacturing elasto-hysteresis elements of the Double Bell vibration isolator from wire material is proposed, characterized in that the stockings are made of a prestressed mesh, in which one of each pair of contacting spirals is elastically stretched and the other elastically compressed by the same load applied along the axis of the spirals.

The use of a prestressed mesh not only improves the dissipative properties of the vibration isolator, but also facilitates the operation of introducing spirals of one layer into the spirals of another layer due to the fact that the mesh layers are elastically stretched and their spirals are in contact with each other.

A method is also proposed for manufacturing the “Double bell” elastic hysteresis elements of the vibration insulator from wire material, characterized in that the spherical billet is formed by winding a continuous strip on a central cylindrical rod, the diameter of which is equal to or slightly larger than the diameter of the bolts fixed to the bell-shaped elements, the turns of the strip are laid overlapping each other on the other, and the axis of the turns either coincide with the axis of the vibration isolator, or are located at small angles to it.

In addition, a method is proposed for manufacturing the “Double Bell” elastic hysteresis elements of the vibration isolator from wire material, characterized in that the stockings are made with a diameter L / π, where L is the scan length of the outline generatrix of the elastic hysteresis element, then the resulting continuous strip is wound on a matrix with the same shape the outer surface, as the inner surface of the elastic hysteresis element, made in one piece with the Central rod with a diameter equal to the diameter of the mounting bolt, and continuous the winding strip is wound so that for each revolution its coil is displaced along the rod, as if along a guide, without a gap by a step equal to the thickness of the strip and the angle of inclination of the cross section of the strip to the axis of the central rod during winding remains constant and equal to the angle of inclination to the axis of the rod tangent to an outline generatrix of the matrix drawn from the top of the angle of inclination located on the axis of the matrix.

The implementation of stockings with a diameter equal to L / π allows one to obtain a finished product in which the concentric axis of the conical elastic-hysteresis element are arranged concentrically in each layer in each layer of the line of adhesion contacts of adjacent spirals, and along its generatrix all spirals in each layer are linked to each other, which significantly increases tensile strength with axial application of tensile load, including compared with the prototype.

With this method of winding the strip and the location of the beginning and end of the strip in the same radial section of the spiral, the stocking will undergo elastic tension, the greater the closer the spiral is to the larger base of the matrix.

The proposed design of vibration isolators DKChP and methods for the manufacture of their elastic hysteresis elements are illustrated by drawings. In the drawings, details related to technological equipment, a vibration-insulated object, and a base on which vibration isolators are mounted are shown by a thin solid line as a “situation” in the assembly drawing. Structurally, the same parts and assembly units of different variants of the DKChP vibration isolator are indicated by the same position in the drawings. The gaps in the drawings are conventionally indicated by size. The structure of the continuous strip, billet and UGE in the drawings is shown conditionally: the right-hand spirals on the main view are designated as “//////” and in the cross section or side view - “)”, the left-hand spirals are respectively indicated as: “\ \ \ \ \ \ "," (".

In FIG. 1 shows a longitudinal section of a vibration isolator DKChP, UGE which are fastened with a compression spring, twisted from one wire.

In FIG. 2 shows a top view of this vibration isolator.

In FIG. 3 shows a longitudinal section of a vibration isolator DKChP, UGE which are fastened by a spring, a retinue of three wires.

In FIG. 4 shows a longitudinal section of a vibration isolator DCCHP, UGE of which is fastened by a spring, in which one supporting coil is bent to the bell flange, and the other with a gap on its conical part. In FIG. 4 shows a variant with two clamps installed in the holes in the bell flanges.

In FIG. 5 shows a longitudinal section of a vibration isolator DKChP with increased bearing capacity.

In FIG. Figure 6 shows a longitudinal section of a DKChP vibration isolator with its UGE unloading from the weight of a vibroinsulated object attributable to the vibration isolator before installing the vibroinsulated object on the vibration isolators.

In FIG. 7 shows a vibration isolator (FIG. 6) after fixing a vibration-isolating object thereon.

In FIG. Figure 8 shows a longitudinal section of a DKChP vibration isolator with its UGE unloading from the weight of a vibroinsulated object falling on a vibration isolator with unloading springs of great flexibility.

In FIG. Figure 9 shows a longitudinal section of a DKChP vibration isolator with unloading its UGE from the weight of the vibroinsulated object attributable to the vibration isolator, in which the UGE is fastened by three springs - a cylindrical and two conical.

In FIG. 10 depicts the formation of a continuous strip of stockings made of a mesh woven from spirals of the right twist, and a stocking of spirals of the left twist.

In FIG. 11 conventionally depicts the formation of a spherical UGE billet by winding a continuous strip on a central rod. Stocking joints not shown.

In FIG. 12 conventionally depicts the formation of a UGE blank from a continuous strip by winding it onto a matrix. The location of the ends of the strip and the joints of the stockings are not shown.

The proposed vibration isolator “Double bell” (DKCHP) (see Fig. 1), contains two elastic hysteresis elements 1, made in the form of bell-shaped elements - bells made by cold pressing of wire material, mounted on top of each other by bases 2, fastened around the periphery of the bases compression spring 3, bolts 4, mounted on bells 1 with profiled restriction washers 5 and nuts 6, and shockproof cushion 7 made of MP wire material, mounted on the head of one of the LTL 4. Elastic hysteresis elements 1 are made below by the proposed method (see Figs. 10, 11 and 12) from stockings 8, woven from wire spirals 9 of the right twist, stretched to step t, determined from the range of values D <t≤D + d, where D is the diameter of the spiral, d is the diameter of the wire, and the stocking 10, woven from spirals 11 with the same parameters, but the left twist. In the body of each elastic hysteresis element 1, the layers 12 formed by a turn of the stocking 8 (each layer is formed by one turn) alternate with the layers 13 formed by the turn of the stocking 10 with spirals of the left twist. The supporting base 2 of each bell 1 (see Fig. 1) is made in the form of a cylindrical flange 14, smoothly passing into the conical part 15 of the bell. The support coils 16 of the spring 3 or springs 3 (see Fig. 1 and 2), twisted close to each other and protruding from the screwed part, are deformed in the radial directions and bent onto the cylindrical flanges 14 so that with 17 bases distributed over the support platforms 2 force the bells 1 to each other. Between each external supporting coil 16 of the spring 3 or springs 3 and the base of the conical part of the bell 1, the radial concentric axis of the vibration isolator has a gap 18 either absent or there is some amount of this gap. For this, the end 19 of each of the outer support coils 16 is cut so that each outer support coil 16 of the spring 3 or springs 3 after its deformation in radial directions has a circle shape with a center on the axis of the vibration isolator, and the sharp edges of the shear contour are rounded.

Between the turns of the cylindrical part of the spring 3 and the cylindrical outer surface 20 of the support base 2 of each bell 1 (see Fig. 1) there is a concentric gap 21, the size of which is the smallest possible, but such that it provides a free increase in the outer diameter of the bases 2 of the bell with working compression deformations along the axis of the vibration isolator.

A double bell vibration isolator (DCBP) (not shown) is also proposed, characterized in that the stockings are made of a prestressed mesh, in which one of each pair of contacting spirals is elastically stretched and the other is elastically compressed by the same load applied along the axis spirals.

A “Double bell” vibration isolator (DKCHP) (not shown) is proposed, in which the force of pressing the bells against each other is ensured by elastic tensile deformation of the fastening spring in the direction of the axis of the vibration isolator.

A double bell vibration isolator (DCBP) is proposed (see Fig. 3), in which the fastening spring 22 is retinued of two, three or more wires 23 (Fig. 3 shows a vibration isolator with a spring 22, twisted of three wires 23). All offered vibration isolators DKChP can be used without shockproof pillow. Moreover, the bolt heads of these vibration isolators are recessed in the body of the bells 1. In FIG. 3, 4, 5, 6, 7, 8, 9 show the proposed vibration isolators DKChP without shockproof pillows.

In addition, it is proposed vibration isolator “Double bell” (DKCHP) (see Fig. 4), characterized in that one of the support turns 16 of each end of the fastening spring 3 is bent to the flange 14 of the bell 1, and the second to the part of the smooth transition from the flange 14 to the conical part 15 of the bell or to its conical part 15 with some pressing force or with a small gap 24.

A vibration isolator is also proposed (see Fig. 4), in which one or two diametrically located through holes 25 are made in the flanges 14 of the bells 1, into which the clips 26 are inserted, made in the form of a bracket made of steel wire, the ends of which are bent into radially located grooves 27 in the flanges of 14 bells 1 flush with their outer surface.

In addition, it is proposed vibration isolator "Double bell" (DKCHP) (see Fig. 5), characterized in that on its elastic hysteresis elements 1 are installed on the outside two spiral compression springs 28 having a cylindrical 29 and a conical part 30, twisted of one, three and more wires 31. Cylindrical parts 29 are tightened with each other so that the first turn 32 of the cylindrical part 29 of each spring 28 protrudes outward from the screwed part 33 of these springs, is deformed in radial directions and bent to a cylindrical flange 14 of each bell 1 in the same way as the coils of the fastening spring of the other proposed variants of the DKChP vibration isolator, and the conical part 30 attached to the elastic hysteresis elements 1 with the same bolts 34, which the vibration isolator is attached to the vibration isolating object 35 and the support 36 (see Fig. 7) using elastic washers 37 and nuts 38.

A “Double bell” vibration isolator (DKCHP) is proposed (see Fig. 6), in which the compression springs 39 are made in such a way that after screwing the springs 39 into each other as described above between the end face 40 of the elastic hysteresis element 1 and the counter end 41 of the conical part 42 of each spring 39, a gap 43 remains, the value of which and the parameters of the springs 39 are selected in such a way that the fastening of the bells 1 is reliable and when the vibration-insulated object 35 is placed (see Fig. 7) on vibration isolators without elastic washers mounted on the bolts 34 b and nuts, these gaps are completely selected, or a certain amount of these gaps remains, which is completely selected when fixing with vibration washers 37 and nuts 38 the vibration isolator on the support 36 and the vibration-insulated object 35 on the vibration isolator.

In addition, it is proposed vibration isolator "Double bell" (DKCHP) (see Fig. 8), in which springs 44 are installed on the elastic hysteresis elements 1, the cylindrical part 45 of which is a retinue of three or more wires 46 and the parameters of this part of the springs are selected so that reliability of the fastening of the bells is ensured 1. The conical part 47 of the springs 44 is made up of only one wire 46 of each spring 44, and the parameters of the conical part of the springs are selected so that when installing the vibration-proof object 35 on the vibration isolators Whether partially unloaded uprugogisterezisny element 1 by weight force vibroizoliruemogo object 35 attributable to vibration isolator.

A “Double bell” vibration isolator (DKCHP) is proposed (see Fig. 9), in which the elastic-hysteresis elements - bells 1 are fastened by three compression springs - two conical 48 with great flexibility, twisted from one wire 49, and cylindrical 50 with greater rigidity, twisted from one, two or three wires 51. The conical springs 48 are dressed on the bells 1 all the way into their flanges 14. The two first and last turns 52 of the coil spring 50 are deformed in radial directions so that the conical springs 48 are secured against turning and press the support coils 53 of the conical springs 48 to the flanges 14 of the bells 1 by the force created by the elastic tensile deformation of the coil spring 50. Moreover, the magnitude of this deformation is selected from the condition that the gap between these coils is not installed when the vibration insulated object 35 is installed on the vibration isolator and the vibration isolator is used up. Between the ends 40 of the elastic hysteresis elements 1 (see Fig. 6) and the counter ends 41 of the conical springs 48 there are gaps 43, the size of which and the parameters of the springs 48 are selected so that they are completely selected when the vibration-insulated object 35 is placed on the vibration isolators (see Fig. 9), and this creates the required amount of force that presses the support coils of the conical springs against the elastic hysteresis elements, and in this position the vibration isolator is attached to the vibration-insulated object 35 and the support 36 using elastic washers 37 and nuts 38.

A method is proposed for manufacturing the elastic hysteresis elements of the proposed “Double Bell” vibration isolator (DCBP) from wire material (see FIGS. 10 and 11) by pressing a workpiece along the axis of the vibration isolator, which is previously made from a mesh formed in the form of a stocking, woven from wire spirals stretched to step t, determined from the range of values D <t≤D + d, so that the axis of the spirals are parallel to the generatrix of the stocking. One part of the stocking 8 is woven from the spirals 9 of the right twist, and the other part of the stocking 10 - from the spirals 11 of the left twist. A continuous strip 54 is formed (see FIG. 10) from layer 12 with stockings 8 from right-hand spirals and layer 13 with stockings 10 from left-hand spirals. By compression, the coils of the coils of one layer are introduced into the coils of another layer along the entire length of the strip 54 without compression of the coils of the coils. In each layer of the continuous strip 54, stockings are laid end to end to each other, and the joints of the stockings in different layers are spaced so that they are approximately evenly distributed around the circumference of the workpiece and the length of the strip 54 is such that after the required number of turns of the strip 54 its ends 55 (see Fig. 11) were located in one radial section of the workpiece 56 against each other and, therefore, in each radial section of the elastic hysteresis element 1 (see Fig. 1) there was the same number of layers of continuous Systems 54. A spherical blank 56 is formed by winding a continuous strip 54 onto a central cylindrical rod 57, the diameter of which is equal to or slightly larger than the diameter of the bolts fixed to the bells. The turns of the strip 54 are stacked overlapping one another, and the axis of the turns either coincides with the axis of the vibration isolator or are located at small angles to it. Formed blank 56 is pressed.

In the finished bells, holes 25 can be punctured (see Fig. 4) and grooves 27 are stamped.

In addition, a method is proposed for manufacturing the elastic hysteresis elements of the proposed “Double Bell” vibration isolator (DCB) from wire material (see FIG. 12), characterized in that the stockings 8 and 9 (see FIG. 10) are made with a diameter L / π, where L is the scan length of the outline generatrix of the elastic hysteresis element 1 (see Fig. 1). A continuous strip 54 is formed (see FIG. 10) from layer 12 with stockings 8 and layer 13 with stockings 9. By compression, the coils of one layer are introduced into the coils of another layer along the entire length of the strip 54 without compression of the coils of coils. The resulting continuous strip 54 (see FIG. 12) is wound on a matrix 58 with the same outer surface shape as that of the inner surface of the elastic hysteresis element, made integrally with the central shaft 59 with a diameter equal to the diameter of the fixing bolt 4 (see FIG. one). Moreover, a continuous strip 54 (see Fig. 12) is wound so that for each revolution, its turn 60 is displaced along the rod 59, as along the guide, without a gap by a step equal to the thickness of the strip 54, and the angle of inclination of the cross section of the strip 54 to the axis of the central rod 59 during winding remained constant and equal to the angle of inclination to the axis of the rod 59 tangent to the outline generatrix of the matrix 58, drawn from the top of the angle of inclination located on the axis of the matrix.

In addition, a method for manufacturing elasto-hysteresis elements of the proposed “Double bell” vibration isolator (DCB) from a wire material (not shown) is proposed, characterized in that the stockings are made of a prestressed mesh, in which one of each pair of contacting spirals is elastically stretched and the other elastically compressed by the same load applied along the axis of the spirals.

The assembly of the vibration isolator DCCHP (Fig. 1) is as follows.

On the elastic hysteresis elements - bells 1, bolts 4 are fixed using restrictive profiled washers 5 and nuts 6. Moreover, one of the bolts 4 is fed to the assembly with a shockproof cushion 7 mounted on its head made of MP material. The bell-tightening compression spring 3 is supplied to the assembly with already plastically deformed in the radial directions to the axis of the spring 3 and in the direction of the axis of the vibration isolator by supporting turns 16 of one of the ends of the spring. Moreover, the support coils 16 are deformed in such a way that when the spring 3 is mounted on the bell 1, they fit snugly against the bell flange 14. The spring 3 is mounted on one of the bell 1. A second bell 1 is mounted on this bell 1. The support coils 16 of the second spring end face 3 are plastically deformed radially. Then, the support coils 16 are plastically deformed by the force directed along the bell axis so that they fit snugly on the bell flange 14 and at the same time the bells 1 supporting platforms 17 pressed against each other with the required force, equally distributed over the area of the platform 16. The device needed to perform these operations nd, not described. The assembled vibration isolator control the concentricity of the gap 20.

Note that it is possible to assemble the vibration isolator in such a way that the force of pressing the bells against each other will be ensured by the elastic tensile strain of the fastening spring. In this case, the assembly of the vibration isolator will require more sophisticated technological equipment, since in this case the support coils must be plastically deformed in this way by a previously elastically stretched spring.

When fixing the bells 1 from mutual rotation with the help of scrapings 26 (see Fig. 4), the bells 1 are first mounted on top of each other and the clips are inserted into the holes 25 in the flanges 14 of the bells 1. The ends of the clips are folded into the grooves of the flanges flush with their outer surface. The fastening spring 3 is installed on the bells 1. The rest of the vibration isolator assembly (Fig. 4) differs little from the vibration isolator assembly already described (Fig. 1).

The assembly of vibration isolators DCCHP (Fig. 3) differs little from that described and therefore is not described.

The assembly of vibration isolators DCCHP (Fig. 5, 6, and 8) also differ little from each other. Therefore, we describe only the assembly of the vibration isolator DCCHP (Fig. 8).

Bolts 34 are installed in the elastic hysteresis elements 1. The elastic hysteresis elements 1 are mounted on top of each other and the fastening springs 44 are put on the bolts 34 until they stop against each other by the cylindrical parts 45. Screw both springs 44 into cylindrical parts 45 so that the first turns 32 of the springs 44 are fully exposed. They are plastically deformed in radial directions and bent on the flanges 14 of the first turns 32 so that the elastic-hysteresis elements 1 are pressed against each other with a given load uniformly distributed over the supporting platforms 17 of the elastic-hysteresis elements. Install the elastic washers 37 on the bolts 34 and screw the nuts 38. In the workplace, the nuts 38 and the elastic washers 37 are removed from the vibration isolator. The vibration isolator is mounted on the support 36 and the vibration insulated object 35 on the vibration isolator and the vibration isolator is mounted on the support 36 and the vibration insulated object 35 on the vibration isolator with the same elastic washers 37 and nuts 38, while the gaps 43 are completely selected.

The vibration isolator DCCH (Fig. 9) is collected as follows.

Bolts 34 are installed in the elastic hysteresis elements 1. The elastic hysteresis elements 1 are mounted on top of each other and the conical springs 48 are put onto the bolts 34 until they stop in the flanges 14 of the elastic hysteresis elements 1. A cylinder spring 50 is fastened to the elastic hysteresis elements 1. The cylindrical spring 50 is stretched and plastically deformed into radial directions and bend to the support turns 53 of its first and last turns 52 so that the conical springs 48 are fixed from unscrewing and press the support turns 53 onicheskih springs 48 against the flanges 1 14 bells force generated by the coil spring 50 of the elastic stretching deformation, the magnitude of this deformation is selected from the conditions to prevent occurrence of the gap between the coils when installed on the vibration isolator vibroizoliruemogo object 35 and the operating time of the vibration insulator. Install the elastic washers 37 on the bolts 34 and screw the nuts 38. In the workplace, the nuts 38 and the elastic washers 37 are removed from the vibration isolator. The vibration isolator is mounted on the support 36 and the vibration insulated object 35 on the vibration isolator and the vibration isolator is mounted on the support 36 and the vibration insulated object 35 on the vibration isolator with the same elastic washers 37 and nuts 38, while the gaps 43 are completely selected.

The manufacture of elasto-hysteresis elements of the DKChP vibration isolators by the proposed methods is clear from the descriptions of the contents of these methods and does not need additional explanations.

The proposed vibration isolators DCT spatial loading. They work on all types of load - periodic, shock, random, etc., acting on all six degrees of freedom.

They have high dissipative properties. The kinetic energy of the dynamic action is dissipated by them due to the work of the dry friction forces on the mutual slippage of the coils of the spiral wire material of the bells, on the mutual slippage of the bells relative to the support coils of the fastening spring.

When using three-core compression springs during their deformation, a certain amount of energy is also dissipated.

With the same UVC and strength, as in DK type vibration isolators, the proposed DKChP vibration isolators are much more simpler in design and manufacturing technology. As noted above, the manufacturing process can be fully automated, and they can be produced in large batches. At the same time, their market price can be significantly reduced and will be quite acceptable not only for those areas of technology where vibration isolators like DK are currently used, but also in many other areas of technology, and, in our opinion, including household appliances .

Claims (13)

1. The double bell vibration isolator containing two elastic hysteresis elements made in the form of bell-shaped elements made by cold pressing of wire material, mounted on top of each other with bases fastened around the periphery of the bases, bolts fixed to bell-shaped elements using profiled restrictive washers and nuts, and a shockproof pillow made of metal rubber (MP) material, mounted on the head of one of the bolts, characterized in that the elastic-hysteresis elements are made they are made of nets formed in the form of a stocking, woven from wire spirals of the right twist, stretched to a step t determined from the range of values D <t≤D + d, where D is the diameter of the spiral, d is the diameter of the wire, and formed in the form of stockings of nets, woven from spirals with the same parameters, but of the left twist, and in the body of each elasto-hysteresis element, the layers formed by a turn of a mesh formed as a stocking with spirals of the right twist alternate with layers formed by a coil of a mesh formed by a stocking with spirals of left windings, and the supporting base of each bell-shaped element is made in the form of a cylindrical flange smoothly passing into the conical part of the bell-shaped element, and both of these elements are fastened to each other by a spiral compression spring, twisted from one or three wires, or two springs screwed to each other, between the coils of the cylindrical part of the spring or springs and the cylindrical outer surface of the support base of each bell-shaped element there is a concentric gap, the value of which is the smallest possible but it is such that it provides a free increase in the outer diameter of the bases of these elements during working compression deformations along the axis of the vibration isolator, and the support turns are one or two at each end of the spring, or the turns of the springs, twisted close to each other and protruding from the screwed part, are deformed in radial directions and bent over the cylindrical flanges of bell-shaped elements in such a way that these elements are pressed against each other with a force distributed over the support platforms of the bases, and between each external support coil m of a spring or springs and the base of the conical part of the bell-shaped element there is no radial concentric to the axis of the vibration absorber, or there is a certain amount of this gap, for which the end of each of the external support coils is cut so that each external support coil of the spring after its deformation in radial directions has the shape of a circle centered on the axis of the vibration isolator, and the sharp edges of the cut contour are rounded. 2. The “double bell” vibration isolator according to claim 1, characterized in that the nets formed in the form of a stocking are made of a prestressed mesh, in which of each pair of contacting spirals one is elastically stretched and the other is elastically compressed by the same load applied along axis of spirals. 3. The “double bell” vibration isolator according to claim 2, characterized in that the pressing force of the bell-shaped elements to each other is ensured by elastic tensile deformation of the fastening spring in the direction of the axis of the vibration isolator. 4. The “double bell” vibration isolator according to claim 3, characterized in that one of the support turns of each end of the fastening spring is bent to the bell-shaped element flange, and the second to the smooth transition part from the flange to the conical part of the bell-shaped element or to its conical part with some force of pressure or with a small gap. 5. The “double bell” vibration isolator according to claim 4, characterized in that one or two diametrically located through holes are made in the flanges of the bell-shaped elements, into which the clips are inserted, made in the form of brackets from steel wire, the ends of which are bent into radially located grooves in flanges of bell-shaped elements flush with their outer surface. 6. The “double bell” vibration isolator according to claim 5, characterized in that two spiral compression springs are installed on its elastic hysteresis elements from the outside, having cylindrical and conical parts, twisted from one, three or more wires, tightly screwed to each other with cylindrical parts so that the first coil of the cylindrical part of each spring protrudes outward from the screwed part of these springs, is deformed in radial directions and bent onto the cylindrical flange of each bell-shaped element in the same way ohm, as well as the coils of the fastening spring of other proposed variants of the vibration isolator, and the conical part attached to the elastic hysteresis elements with the same bolts that secure the vibration isolator to the vibration isolating object and the support with elastic washers and nuts. 7. The double bell vibration isolator according to claim 6, characterized in that the compression springs are made in such a way that after screwing the springs into each other, gaps remain between the ends of the elastic hysteresis elements and the response ends of the conical parts of the springs, the value of which and the spring parameters are selected in such a way that ensures the reliability of fastening bell-shaped elements and when placing a vibration-insulated object on vibration isolators without elastic washers and nuts mounted on bolts, these gaps are completely selected or remain I have a certain quantity of these gaps, which is fully selected when fixing using spring washers and nuts on the support isolator and vibroizoliruemogo object on vibration isolators. 8. The double bell vibration isolator according to claim 7, characterized in that springs are installed on the elastic hysteresis elements, the cylindrical part of which is a retinue of three or more wires and the parameters of this part of the springs are selected so that the fastening of bell-shaped elements is reliable and the conical part of the springs retinue from only one wire of each spring, and the parameters of the conical part of the springs are selected in such a way that when installing the vibration-insulated object on the vibration isolators, they are completely or partially unloaded and an elastic hysteresis element from the force of the weight of the vibroinsulated object attributable to the vibration isolator. 9. A double bell vibration isolator containing two elastic hysteresis elements made in the form of bell-shaped elements made by cold pressing from wire material, mounted on top of each other with bases fastened around the periphery of the bases, bolts fixed to bell-shaped elements using profiled restrictive washers and nuts, and an anti-shock pad made of metal rubber (MP) material, mounted on the head of one of the bolts, characterized in that the elastic-hysteresis elements are count near-like elements - made of nets formed in the form of a stocking, woven from wire spirals of the right twist, stretched to a step t, determined from the range of values D <t≤D + d, where D is the diameter of the spiral, d is the diameter of the wire, and formed in the form a stocking of nets woven from wire spirals with the same parameters but of the left twist, moreover, in the body of each elasto-hysteresis element, layers formed by a loop formed in the form of a stocking with spirals of the right twist alternate with layers formed by a spiral formed oh in the form of a mesh stocking with spirals of the left twist, and the supporting base of each bell-shaped element is made in the form of a cylindrical flange that smoothly passes into the conical part of this element, and both elements are fastened by three compression springs - two conical with great flexibility, twisted from one wire, and cylindrical with greater rigidity, twisted from one, two or three wires, conical springs are dressed on bell-shaped elements to the end in their flanges, the first and last coil of a cylindrical spring are deformed into radial directions in such a way that they fix the conical springs from unscrewing and press the support coils of the conical springs against the flanges of these elements by the force created by the elastic tensile deformation of the coil spring, and the magnitude of this deformation is selected from the condition of preventing a gap between these coils when installing a vibration-insulated object on the vibration isolator and the operating time of the vibration isolator, and there are gaps between the ends of the elastic hysteresis elements and the counter ends of the conical springs, the value of which the spring parameters are selected in such a way that they are completely selected when a vibration-insulated object is placed on the vibration isolators and the required amount of force is created, which presses the support coils of the conical springs to the elastic-hysteresis elements, and in this position the vibration isolator is attached to the vibration-insulated object and the support using elastic washers and nuts . 10. A method of manufacturing elastic double-bellied hysteresis elements of the “double bell” vibration isolator from wire material by pressing a blank along the axis of the vibration isolator, which is preliminarily made from a mesh formed in the form of a stocking, woven from stretched wire spirals, so that the axis of the spirals is parallel to the generatrix formed in the form of a stocking nets, nets of one part of the nets formed in the form of a stocking are woven from spirals of the right twist, and the other part from spirals of the left twist, do not form tear strip from a layer with nets formed in the form of a stocking from spirals of the right twist and a layer with stockings formed in the form of a stocking from spirals of the left twist and compression introduce coils of one layer into the spirals of another layer along the entire length of the strip without compression of the coils of spirals, and from the resulting strip forming a preform, characterized in that the nets formed in the form of a stocking are weaved from spirals stretched to a step t determined from the range of values D <t≤D + d, where D is the diameter of the spiral, d is the diameter of the wire, and in each layer of a continuous stripthe nets formed in the form of a stocking are laid end to end to each other, and the joints of the nets formed in the form of a stocking in different layers are spaced from each other so that they are approximately uniformly distributed around the circumference in the volume of the workpiece and the strip length is such that after the required number of turns the ends of the strip were located in the same radial section of the workpiece against each other and, therefore, in each radial section of the elastic hysteresis element there was an equal number of layers of the continuous strip. 11. A method of manufacturing an elastomeric hysteresis elements of a double bell vibration isolator from wire material according to claim 10, characterized in that the mesh formed in the form of a stocking is made of a prestressed mesh, in which one of each pair of contacting spirals is elastically stretched and the other is elastically compressed by one and the same load applied along the axis of the spirals. 12. A method of manufacturing an elasto-hysteresis elements of a double bell vibration isolator from wire material according to claim 11, characterized in that the spherical billet is formed by winding a continuous strip on a central cylindrical rod, the diameter of which is equal to or slightly larger than the diameter of the bolts fixed on bell-shaped elements, strip turns stacked with overlapping each other, and the axis of the turns either coincide with the axis of the vibration isolator, or are located at small angles to it. 13. A method of manufacturing an elasto-hysteresis elements of a double bell vibration isolator from wire material according to claim 11, characterized in that the nets formed in the form of a stocking are made with a diameter L / π, where L is the sweep length of the outline generatrix of the elastic hysteresis element, then the resulting continuous strip is wound on a matrix with the same shape of the outer surface as that of the inner surface of the elastic hysteresis element, made in one piece with the Central rod with a diameter equal to the diameter of the mounting bolt and a continuous strip is wound so that for each revolution its coil is displaced along the rod, as along the guide, without a gap by a step equal to the thickness of the strip, and the angle of inclination of the cross section of the strip to the axis of the central rod during winding remains constant and equal to the angle of inclination to the axis rod tangent to the outline generatrix of the matrix drawn from the top of the angle of inclination located on the axis of the matrix.

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