RU2506475C2 - Unloaded vibration isolator of large carrying capacity - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention refers to machine building industry. Vibration isolator includes a housing with a rectangular flange, two elastic sleeves from wire material of metal rubber, which are arranged in it, a cover, a tightening element and fastening parts. A cylindrical wall of the housing projects on both sides of its base to the height of the sleeve in free state. A vibration isolator bottom is attached to the housing flange by screws. The tightening element is made in the form of a hollow cylinder with a round flange. A flat supporting platform with central and threaded holes is made on outer surface of the flange. The tightening element is arranged in central holes of elastic sleeves and the cover. Specified value of axial preload of elastic sleeves is created by tightening of a round nut that is screwed on a threaded end of the tightening element and under which elastic and lock washers are installed. An unloading spiral compression spring with high flexibility is arranged inside the slot of the tightening element. The spring is fixed along the round thread in a support made at the vibration isolator bottom. The cover is screwed from above onto the spring along round thread. Between the cover and the cylinder bottom there arranged is a support the ball stop of which is borne against the spring cover, and its outer surface is borne against the cylinder bottom of the tightening element.

EFFECT: achieving increase in carrying capacity and service life of a vibration isolator.

8 cl, 11 dwg

Description

The invention relates to vibration-isolating all-metal devices of medium and heavy lifting capacity, capable of working in an aggressive environment, in vacuum, in conditions of radiation and elevated temperature (up to 450 ° C).

A known vibration isolator (see Kotov A.S. Calculation of the Elasto-Damping Characteristics of Vibration Isolators from the material MR. // Abstract of the dissertation for the degree of candidate of technical sciences. - Samara - 2007), containing a housing, two conical elastic bushings from wire nonwoven material MR (“Metal rubber”), a cover, a central hub, a collar screw with a shoulder and fasteners - washers, slotted nuts and cotter pins. Small concentric flanges are made on the body, cover and central sleeve, along which MR bushes are centered and a radial interference is created in them. The axial interference in the bushings from MR is created by tightening the lower slotted nut (if the axis of the vibration isolator is vertical) until the cover stops against the collar of the coupling screw and the end of the central sleeve into the cover and in this position the nut is split. The vibration isolator case has a flange, with which the vibration isolator is attached to the base. The vibration-isolating object is placed on the cover and secured with a washer, a second slotted nut and a cotter pin.

The vibration isolator can be used for spatial loading. Its elastic sleeves operate in a two-sided elastic hysteresis stop under loading in all six degrees of freedom. Among its positive qualities should be attributed to its relatively small dimensions and weight, simplicity of design and manufacturing technology.

By technical nature, this vibration isolator is closest to the proposed and adopted as a prototype.

However, this vibration isolator has a number of serious drawbacks.

MR material does not work well in tension, and during torsional and shear vibrations of an object in places of elastic bushings, where they are in contact with centering collars, tensile stresses can occur, leading to local rupture of the material of the bushings.

In the literary source (see Kotov A.S. Calculation of the elastic-damping characteristics of vibration isolators from the MR material. // Abstract of the dissertation for the degree of candidate of technical sciences. - Samara - 2007), where this design of the vibration isolator is described, conditions that it is necessary to perform when creating a workable, heavily loaded vibration isolator with elastic hysteresis elements made of MR material that meets customer specifications, and their physical meaning is not revealed (see below).

The elastic bushings of the vibration isolator are made by unidirectional pressing of the workpiece along the vertical axis of the sleeve. Therefore, the inclination angles to the axis of the sleeve of the planes of the main mass of the turns of the spirals inside its volume differ little from the direct one and with significant radial dynamic loads, residual radial deformations will arise that will quickly increase during running hours.

Unidirectional pressed articles made of MP material work best for compression in the pressing direction.

The prototype of the upper elastic sleeve is significantly more loaded than the lower one, since when loading the vibration isolator with the weight of the object, it is loaded according to the same process that it was loaded when the axial tension was created in it, and the lower elastic sleeve is unloaded and, as a result, is less loaded condition even compared to its state after creating an axial interference in it.

As a result, during dynamic loading of the vibration isolator, the loading of the upper sleeve is described by a hysteresis loop either partially or entirely lying on the “tails” of the field of its elastic hysteresis loops, which significantly worsens the elastic hysteresis characteristics (UVC) of the vibration isolator, increases the overloads and resonant frequencies of the vibration-insulated object, which in turn leads to the appearance of "shrinkage" of the material of the sleeve and reduce the axial interference of the bushings. Moreover, as the operating time increases "shrinkage" and residual radial deformation increases the density of the material of the bushings. In addition, due to wear, friction on the contact surfaces of the coils of spirals increases. All this will lead to the fact that the working hysteresis loop of the vibration isolator will be “pushed” further and further to the “tail” of the field, the average cyclic rigidity of the vibration isolator will increase, and consequently, the resonant frequencies of the “object-vibration isolators” dynamic system, the dispersion coefficient of the vibration isolator will decrease and therefore, dynamic overloads acting on the object will increase. Moreover, the intensity of the increase in the adverse effects of these factors will continuously increase as the operating time. Naturally, the growth rate of these adverse factors strongly depends on the successful selection of the initial design parameters of the vibration isolator.

Among the disadvantages of the prototype should also include the lack of elastic compensation for the loss of axial interference during running, due to the rigid fastening of the cover with the Central sleeve. As a result, as the operating experience of the vibration isolator has shown, by reducing the axial interference, the tightening torque of the slotted nuts is reduced, despite their being secured with cotter pins, and from time to time they have to be tightened and split.

Therefore, the task is to develop a large-capacity vibration isolator (with the same load range or greater than that of the prototype), which, under torsional and shear vibrations of the object, did not “bite” the material of the elastic bushings and local break it, axial “shrinkage” and radial shear residual deformation of the material of the MR bushings during the operating time did not lead to the need for periodic retightening of the slotted nuts and their cottering, while the proposed vibration isolator compared to the prototype would have better UVC, and, therefore, the dynamic system “vibration-isolating object - vibration isolators” would have lower resonant frequencies and the object would be affected by lower dynamic overloads both in the resonance zones and in the resonance ones, and, therefore, the proposed vibration isolator would have a longer service life, than a prototype.

The problem is solved by the fact that the VBGR vibration isolator of large load capacity is proposed, unloaded, comprising a housing with a rectangular flange with holes for attaching the vibration isolator to the support, two conical elastic bushings made of MP wire material made by unidirectional pressing in the direction of the axis, placed in it with a radial and axial interference bushings, a cover, a clamping element and fasteners located in the central hole of the bushings and the cover, characterized in that the cylindrical wall of the protrusion housing it is on both sides of its conical base to the height of the sleeve in the free state, the bottom of the vibration isolator is attached to the housing flange, the coupling element is made in the form of a hollow cylinder with a round conical flange with an outer diameter smaller than the inner diameter of the cylindrical wall of the housing for two strokes of the vibration isolator in the radial direction and on the outer surface of the flange there is a flat supporting platform with a central hole and one, two or more threaded holes, a coupling element with a given radial the thrust is placed in the Central holes of the elastic bushings, and the diameter of the inner hole of the conical base of the housing is two radial strokes greater than the diameter of the smooth cylindrical part of the coupling element, the conical cover is centered on the smooth cylindrical part of the coupling element, and its outer abutment surface is made flat and its outer diameter is the outer diameter of the conical flange of the coupling element, the specified value of the axial tension of the elastic bushings is created by tightening a round nut, which is screwed onto the long end of the clamping element, and under which one, two or more elastic washers are installed, and a lock washer, one whisker of which is bent into the groove of the nut, and the other into the groove of the coupling element, inside of which with a small axial interference there is a unloading spiral compression spring with great flexibility - for example, its deformation under the action of the force of weight G of the vibroinsulated object falling on the vibration isolator can be 5-10 times or more higher than the compression deformation of the elastic bushings when this force is applied to them, the spring is fixed on a round thread and in a support made at the bottom, and on top of the spring, a cap is also screwed on a round thread, the outer diameter of which is two strokes of the vibration isolator in the radial direction less than the diameter of the cylinder’s inner bore of the coupling element, in which the spring, the spring and the cover are unobtrusively the wall of the support and the skirt of the cover, between the cover and the bottom of the cylinder with centering along its inner wall and with the possibility of displacement without distortions along the axis of the vibration isolation, a support is placed, which is a ball stop-ball, rolling When mounted in the shaft with the possibility of free rotation, it rests against the spring cover, and the outer surface into the bottom of the cylinder of the coupling element with a small force created by a small axial tension of the spring, sharp edges of the elastic bushings, the cylindrical wall of the housing, the cover, the conical flange of the coupling element, as well as the place the connections of the wall of the housing with its base and the conical flange with the clamping element are rounded by radii, the fingers of the object, which are locked, are screwed into the paws of the object with which it is placed on the vibration isolators with a nut, which, when installing the object on vibration isolators, enter the central holes of the supporting platforms of the flanges of the coupling elements and wring out the bearings with a spherical stop and springs so that the tabs are pressed against the supporting platform of the flange of the coupling element, and the vibration-insulated object in this position is fixed with screws under each head of which an elastic washer and a lock washer with a folding mustache are installed, and the length of the finger and its threaded part are selected such that it can be ensured by selecting the screwing length of the finger that internal spring of each isolator perceived the full force of the weight of an object falling to the isolator, or only given her a share.

Compared to the prototype, the load due to axial and radial interference is more evenly distributed on all boundary surfaces of the bushings, which significantly improves the UVC of the proposed vibration isolator. In the prototype, when the vibroinsulator is loaded with constant force G and dynamic cyclic force with a maximum amplitude specified by the technical specifications, the deformation of the bushings under the action of a constant force will be several times greater than the deformation of these bushings under the action of only one constant force, since the center of the hysteresis loop under the action of constant force will shift to a point with an ordinate G process with a stiffness equal to the least rigidity from the stiffnesses of the processes limiting this loop, and elastic bushings operating in the bilateral elastic mode terezisnogo stop will be loaded on the hysteresis loop or lying entirely in the "tail" of the field uprugogisterezisnyh loops or partially exciting "tail", which greatly impairs the UFH isolator and lead to the above consequences.

The proposed vibration isolator elastic bushings are fully or partially unloaded from the action of constant force G.

As a result, its elastic bushings in the entire operating range are loaded loops without “tails”, which significantly improves the UVC of the vibration isolator - significantly reduces the average cyclic rigidity of the bilateral elastic hysteresis stop (bushings) and increases its dispersion coefficient. Moreover, the average cyclic rigidity of the entire vibration isolator, taking into account the rigidity of the unloading spring, may turn out to be significantly lower than that of the prototype, since in this case elastic bushings made of lower density MP material can be used.

As a result, the use of the proposed vibration isolator will reduce the dynamic overloads acting on the system “vibration isolating object - vibration isolators”, expand the range of permissible dynamic loads, reduce the resonant frequencies of the system, significantly reduce the rate of increase of the “shrinkage” of the bushings and the deterioration of the UVC of the vibration isolator during operation, and therefore increase the resource of its operation.

The absence of flanges of the proposed vibration isolator at the housing, cover and flange of the coupling element, along which the elastic bushings are centered in the prototype and tensioning is created in them, the presence of rounding of sharp edges at the housing wall, flange of the coupling element and cover in contact with the material of the elastic bushings, and rounding of sharp the edges of the elastic bushings themselves exclude the possibility of "biting" the material of the bushings and the appearance of local gaps in the material.

The installation of elastic washers under the round nut and the heads of the fixing screws eliminates the unacceptable weakening of their tightening during running hours and, therefore, there is no need to re-tighten and lock during operation.

The smallest residual deformation and the rate of its accumulation during running time, all other things being equal, are obtained for products made of wire material MR working for cyclic compression. The accumulation time of residual deformation to an unacceptable size determines the resource of these products.

Therefore, in order to increase the life of the vibration isolator, a VBGR high-capacity vibration isolator is proposed, unloaded, characterized in that the elastic bushings are made by sequential pressing of the workpiece in radial and axial directions, and the degree of deformation of the workpiece in each of these operations - pressing phases is selected so that the planes of the spiral turns the bulk of the turns in the volume of the sleeve are inclined to the vertical axis of the vibrator at angles φ lying within 45 ° ≤φ≤α, where α is an angle equal to half e of the angle of the cone of the sleeve.

In this case, the proportion of shear deformations of elastic bushings during their radial dynamic loading decreases and the rate of increase in the residual shear strain of the bushings decreases, thereby increasing the life of the vibration isolator.

In order to increase the elastic-hysteresis properties of the vibration isolator, a VBGR vibration isolator is proposed, characterized in that its discharge spring is made of three wires.

In view of the complexity of manufacturing a three-core spring with a large load-carrying capacity, the load-bearing capacity of this vibration isolator should be less than that of the previous design, and the elastic-hysteresis element of the vibration isolator is unloaded only partially from the action of force G.

In order to improve the shockproof properties of the vibration isolator, a VBGR vibration isolator is proposed, characterized in that a shockproof pillow made by axial pressing of high density MP material is fixed to its bottom.

In addition, a VBGR vibration isolator is proposed, characterized in that it is made with cylindrical elastic bushings, the angles of inclination of the plane of the turns to the vertical axis of the sleeve at the bulk of the turns of the material of the sleeve differ slightly from 45 °, and the housing base, cover and flange of the coupling element are made flat supporting surfaces.

In order to improve the UVC of the vibration isolator and to protect it from dust and dirt, a VBGR vibration isolator is proposed, characterized in that distance spacers are installed between the flange of the coupling element and the elastic sleeve and between the cover and the other elastic sleeve, with a central hole with a diameter of equal to the diameter of the opening of the base of the housing, and the sharp edges of the spacers are rounded with radii.

The use of distance spacers improves the plot of the distribution of compressive axial load on the supporting surfaces of the elastic bushings, and, therefore, improves the UVC of the vibration isolator, and prevents dust and dirt from entering the elastic bushings.

In the considered designs of VBGR vibration isolators, the shear stiffness of the discharge spring is practically not included in the shear stiffness of the vibration isolator due to the small rolling friction forces between the ball of the ball stop and the spring cover.

If the resonant frequencies of shear vibrations of the object, obtained when the shear stiffness of the discharge spring is turned on in radial directions, are acceptable, then the design of the proposed vibration isolator can be simplified due to the lack of support with a ball stop in its design.

A VBGR vibration isolator is proposed, characterized in that the spring cover in the unloaded condition of the vibration isolator by the force created by the axial tension of the discharge spring is pressed directly to the bottom of the coupling element cylinder, and there is a concentric gap between the cover and the cylinder wall slightly less than or equal to the radial direction of the vibration isolator.

In this case, for small shear radial displacements of the spring, at which the finger does not slip relative to the cover, the shear stiffness of the spring is fully included in the shear stiffness of the vibration isolator, and for shear displacements, at which the mutual sliding of these elements occurs, we can approximately assume that the shear the stiffness of the vibration isolator includes the cyclic stiffness of the hysteresis loop, along which these elements are loaded during shear deformation of the vibration isolator, and this the stiffness is less than the shear stiffness of the spring in radial directions.

In addition, a VBGR vibration isolator is proposed, which differs from the previous one only in that the spring cover is centered on the cylinder wall of the coupling element and can move without jamming along the cylinder axis, and there is a concentric gap between the spring and cylinder wall, slightly smaller or equal to the course of the vibration isolator in the radial directions.

In this case, at any permissible displacements of the vibration isolator, the entire shear stiffness of the discharge spring is included in the shear stiffness of the vibration isolator.

The designs of the proposed vibration isolators are illustrated by figures in which the mounting of the vibration isolator to the object and the base is shown as a “situation” in the assembly drawing by a thin solid line.

Figure 1 shows a section along aa in figure 2 of the VBGR vibration isolator with tapered bushings.

Figure 2 shows a top view of this vibration isolator.

Figure 3 shows a section along aa in figure 2 of the VBGR vibration isolator with tapered bushings, after fixing the vibration-isolating object on it.

Figure 4 shows a section along aa in figure 2 of the VBGR vibration isolator with tapered bushings with shockproof cushion.

Figure 5 shows a section along aa in figure 2 of the VBGR vibration isolator with conical bushings, a three-core unloading spring and an anti-shock pad.

Figure 6 shows a possible embodiment of the VBGR vibration isolator with tapered bushings.

7 shows a VBGR vibration isolator with cylindrical bushings.

On Fig depicted VBGR vibration isolator with cylindrical bushings, spacers and shockproof pad.

Figure 9 shows a fragment of the VBGR vibration isolator with cylindrical bushings, with spacers, in the delivery state, with the cover of the unloading spring directly resting on the bottom of the cylinder of the coupling element, with a concentric gap between the cover and the cylinder wall.

Figure 10 shows a fragment of the same vibration isolator, but with the cover of the discharge spring, centering on the cylinder wall of the coupling element.

Figure 11 shows a qualitative view of the field of elastic hysteresis loops of elastic sleeves during cyclic loading of a vibration isolator with various types of loads.

The proposed VBGR vibration isolator of large capacity, unloaded (see Figs. 1 and 2) contains a housing 1 with a rectangular flange 2 with holes 3 for attaching a vibration isolator to the base 4 (see Fig. 3), two conical radially and axially tightened in it elastic bushings 5 (see Fig. 1) of MP wire material made by unidirectional pressing in the direction of the axis of the bush, a conical cover 6 placed in the central hole 7 of the bushings 5 and the cover 6, the coupling element 8, the unloading spiral compression spring 9, the spring cover 10 , opo at 11 with a spherical abutment 12 crimped therein with freedom of rotation of ball 13, the bottom 14 and the fasteners.

The cylindrical wall 15 of the housing 1 projects on both sides of its conical base 16 to the height of the sleeve 5 in a free state. The bottom 14 with screws 17 is attached to the flange 2 of the housing 1. The coupling element 8 is made in the form of a hollow cylinder 18 with a round conical flange 19 with an outer diameter smaller than the inner diameter of the cylindrical wall 15 of the housing 1 for two strokes of the vibration isolator in the radial direction, and on the outer surface of the flange 19, a flat supporting platform 20 is made with a central hole 21 and one, two or more threaded holes 22 (see FIGS. 1 and 2). The coupling element 8 (see Fig. 1) with a given radial tightness is placed in the central holes 7 of the elastic bushings 5, the diameter of the inner hole 23 of the conical base 16 of the housing 1 is two radial strokes greater than the diameter of the smooth cylindrical part 24 of the coupling element 8. The conical cover 6 is centered on the smooth cylindrical part 24 of the coupling element 8, and its outer supporting surface 25 is made flat. The outer diameter of the cover 6 is equal to the outer diameter of the conical flange 19 of the coupling member 8. The predetermined axial tension of the elastic sleeves 5 is created by tightening the round nut 26, which is screwed onto the threaded end of the coupling member 8, and under which one, two or more elastic washers 27 are mounted, and lock washer 28, one whisker bent into the groove of the nut 26, and the other into the groove of the coupling element 8. Inside the coupling element 8 with a small axial interference, an unloading spiral compression spring 9 with great flexibility is placed - for example, its deformation I, under the action of the force of weight G of the vibroinsulated object attributable to the vibration isolator, can be 5-10 times or more greater than the compressive strain of the elastic bushings 5 when this force is applied to them. The spring 9 is fixed on a round thread in a support 29 made on the bottom 14. A cover 10 is also screwed on top of the spring 9 on a round thread 9, the outer diameter of which is two times the vibration isolator in the radial direction less than the diameter of the inner hole 30 of the cylinder 18 of the coupling element 8, in which placed spring. The spring 9 and the cover 10 from turning off are locked by dents 31 on the wall of the support 29 and the skirt of the cover 10. Between the cover 10 and the bottom 32 of the cylinder 18 with centering along its inner wall and with the possibility of displacement without distortions along the axis of the vibration isolation placed support 11, which ball stop 12 , the ball 13, rolled into it with the possibility of free rotation, abuts against the cover 10 of the spring 9, and the outer surface of the bottom 32 of the cylinder 18 of the coupling element 8 with a small force created by a small axial interference of the spring. The sharp edges of the elastic bushings 5, the cylindrical wall 16 of the housing 1, the cover 6, the conical flange 19 of the coupling element 8, as well as the junction of the wall 15 of the housing 1 with its base 16 and the conical flange 19 with the coupling element 8 are rounded with radii. In the paws 33 of the object 34 (see Fig. 3), by which it is placed on the vibration isolators, fingers 35 screwed by a lock nut 36 are screwed to a predetermined length, which, when the object 34 is mounted on the vibration isolators, enter the central holes 21 of the bearing pads 20 of the flanges 19 of the coupling elements 8 and press the supports 11 with the ball stop 12 and the spring 9 so that the tabs 33 are pressed against the supporting platform 20 of the flange 19 of the coupling element 8, and the vibration-insulated object in this position is fixed with screws 37. An elastic washer 38 and a lock washer are installed under each screw head 37. 39 with a mustache. The length of the finger 35 and its threaded part are selected such that by selecting the screw-in length of the finger, it can be set so that the unloading spring 9 of each vibration isolator perceives all the weight of the object 34 attributable to this vibration isolator, or only its predetermined proportion. The vibration isolator with screws 37, under the heads of which elastic washers 38 and lock washers 39 are also mounted, is fixed on the base 4.

The elastic bushings 5 can be made by sequentially pressing the workpiece in radial and axial directions (not shown in the figure), and the degree of deformation of the workpiece in each of these operations - pressing phases is selected so that the plane of the coils of the spirals of the main mass of coils in the volume of the sleeve is inclined to the vertical the vibrator axis at angles φ lying within 45 ° ≤φ≤α, where α is the angle equal to half the angle of the sleeve cone.

The following constructions of the VBGR vibration isolator of heavy lifting capacity, unloaded, with conical and cylindrical elastic bushings are also proposed (the structures of these vibration isolators are clearly visible in the figures and are not described in detail):

VBGR vibration isolator (see Fig. 4) with a shockproof pad 41 fixed in its bottom 40 made by axial pressing of high density MP material

VBGR vibration isolator (see Fig. 5) with a discharge spring 42 woven from three cores;

VBGR vibration isolator made in the embodiment shown in Fig.6, which mainly differs in the design of the bottom 43 of the vibration isolator;

VBGR vibration isolator (see Fig. 7), made with cylindrical elastic bushings 44, in which the angles of inclination of the planes of the turns to the vertical axis of the sleeve at the bulk of the turns of the material of the sleeve differ little from 45 ° (not shown in Fig.), and the base 45 of the housing 46, the cover 47 and the flange 48 of the coupling member 49 are made with flat abutment surfaces;

VBGR vibration isolator (see Fig. 8), in which distance spacers 50 are mounted between the flange 48 of the coupling element 49 and the elastic sleeve 44 and between the cover 47 and the other elastic sleeve 44, with a central hole 51 with a diameter equal to the diameter of the hole 52 of the base 45 of the housing 46, and the sharp edges of the spacers 50 are rounded with radii;

VBGR vibration isolator (see Fig. 9), in which the cover 53 of the spring 54 in the unloaded condition of the vibration isolator by the force created by the axial interference of the discharge spring 54 is pressed directly to the bottom 55 of the cylinder 56 of the coupling element 49, and there is a concentric gap between the cover and the wall of the cylinder 56 57, slightly smaller or equal to the course of the vibration isolator in radial directions;

VBGR vibration isolator (see Fig. 10), whose cover 53 of the spring 54 is centered along the cylinder wall 56 of the coupling element 49 and is able to move without jamming along the cylinder axis, and there is a concentric gap 58 between the spring 54 and the cylinder wall 56, slightly smaller or equal the vibration isolator in radial directions ..

The assembly of various variants of the proposed VBGR vibration isolators differs little from each other. Therefore, we consider only the assembly of the VBGR vibration isolator (Figs. 1 and 2).

Elastic bushings 5 are installed in the housing 1. To install the coupling element 8 and create a radial interference in the bushings 5, a technological intake cone is used. Depending on the height of the sleeve 5 and the design of the coupling element 8, it can be screwed onto the threaded end of the coupling element until it stops in the smooth part of its cylinder 18, or screwed into this cylinder until it stops at its end, or not connected to the coupling element 8 ( technological intake cone and possible options for its use are not shown in the figure). The smaller diameter of the intake cone is less than the diameter of the central hole of the sleeve 5 in the free state, and the larger is equal to or slightly larger than the diameter of the smooth part of the cylinder 18 of the coupling element 8. With a predetermined radial interference, the coupling element 8 (with the intake cone) is inserted into the central holes 7 of the elastic bushings 5 to stop flange 19 into the elastic sleeve 5 and remove the technological intake cone. Sequentially put on the coupling element 8 a cover 6, one, two or more elastic washers 27 and a lock washer 28, screw a round nut 26, tighten it until a predetermined axial tightness is created in the elastic bushings 5, which is controlled by the size between the outer end face of the round nut 26 and the flat bearing pad 20 of the flange 19. Then, the round nut 26 is checked. The spring 9 is screwed into the support 29 of the bottom 14 and the cover 10 is screwed on it. The spring 9 and the cover 10 are checked with indentations 31 of the wall of the support 29 and the skirt of the cover 10. Install the support 11 s ball joint 12 and bottom 14 with cm mounted on it with a spring 9 and a cover 10 and fasten the bottom 14 to the housing 1 with screws 17, which from unscrewing will counter with paint so that the paint does not interfere with the exact installation of the vibration isolator in the workplace.

At the workplace, VBGR vibration isolators (see Fig. 3) are attached to the base 4 with screws 37 using elastic washers 38 and lock washers 39. Fingers 35 are screwed into the tabs 33 of the vibration-insulated object 34 to a predetermined length and nuts are secured by nuts 36. The object 34 is mounted on vibration isolators, while the tabs 33 will be installed on the supporting platforms 20 of the vibration isolators. Fasten the object 34 to the vibration isolators with screws 37, elastic washers 38 and lock washers 39.

At any load of the VBGR vibration isolator, its elastic bushings operate in the bilateral elastic hysteresis stop mode - either one bush is loaded, the other is unloaded, or one half of each bush is loaded, and the other half is unloaded. When the elastic bushings are completely unloaded from the action of a constant force G - the weight of the vibroinsulated object acting on the vibration isolator, its elastic bushings under the action of periodic dynamic load on it are loaded according to the processes of the field of elastic-hysteresis loops shown in Fig. 11 with a thickened solid line. The parameters of the proposed VBGR vibration isolators are selected in such a way that under the action of dynamic loads less than or equal to permissible, the “working” loops 59 (see FIG. 11) were without “tails” 60 or, if necessary, with small “tails”. During shock loading, the vibration isolator can be loaded according to the “tail” process.

The center of the field of "working" loops lies at the point O (0,0) - the unloaded state of the elastic bushings. In this case, the proposed VBGR vibration isolators will have the best possible UVC and, therefore, the operating range of the vibration isolator will be wider, the resonant frequencies of the “vibration-insulated object-vibration isolators” system will be lower and lower than the dynamic overloads acting on the object, both at resonances, and in non-resonant work areas. Therefore, the life of the vibration isolators will be large.

The proposed VBGR vibration isolators work with all types of dynamic load acting across all six degrees of freedom. They have a damping of 2.5-3 times greater and allow a specific dynamic load (in terms of a unit volume of an elastic hysteresis element), five times greater than that of vibration isolators with rubber elastic hysteresis elements. With a large carrying capacity, their dimensions will be significantly smaller than the dimensions of vibration isolators of the same carrying capacity with rubber elastic hysteresis elements. They are designed and can be operated in an aggressive environment, in conditions of radiation, vacuum and elevated temperature. Their advantages compared to the prototype described above.

In addition, in most practical cases, various components of the object’s weight will act on the vibration isolators and, at the workplace, screwing the finger 35 to different lengths of the tabs 33, the elastic bushings of the VBGR vibration isolators can be completely relieved from the action of these components.

Claims (8)

1. The heavy-duty vibration isolator, comprising a housing with a rectangular flange with holes for attaching the vibration isolator to the support, two conical or cylindrical elastic bushings made of metal rubber wire made in it with radial and axial interference, made by unidirectional pressing in the direction of the sleeve axis, a cover placed in the central hole of the bushings and cover, a coupling element and fasteners, characterized in that the cylindrical wall of the housing protrudes from both sides of its the height of the sleeve in the free state, the bottom of the vibration isolator is attached to the flange of the housing with screws, the coupling element is made in the form of a hollow cylinder with a round flange with an outer diameter smaller than the inner diameter of the cylindrical wall of the housing for two radial direction of the vibration isolator, made conical for conical elastic bushings or cylindrical for cylindrical elastic bushings, and on the outer surface of the flange is made a flat supporting platform with a Central hole and one, two or more cut bby holes, the clamping element with a given radial interference is placed in the central holes of the elastic bushings, the diameter of the inner hole of the housing base, conical for conical elastic bushings and flat for cylindrical elastic bushings, two radial strokes greater than the diameter of the smooth cylindrical part of the coupling element, the cover is made conical for conical elastic bushings and flat for cylindrical elastic bushings and is centered on the smooth cylindrical part of the coupling element, and its outer support the surface is flat, and its outer diameter is equal to the outer diameter of the flange of the coupling element, the specified value of the axial interference of the elastic bushings is created by tightening a round nut that is screwed onto the threaded end of the coupling element and under which one, two or more elastic washers and a lock washer are installed, one the whisker of which is bent into the groove of the nut, and the other into the groove of the clamping element, inside of which with a small axial interference there is a unloading spiral compression spring with great flexibility, for example, its deformation under The action of the weight force G of the vibration-insulating object falling on the vibration isolator can be 5-10 times or more greater than the compression deformation of the elastic bushings when this force is applied to them, the spring is fixed on a round thread in a support made on the bottom, and on top of the spring also round a screw is screwed onto the thread, the outer diameter of which is two strokes of the vibration isolator in the radial direction less than the diameter of the inner bore of the clamping element cylinder, in which the spring, spring and the cover are locked by dents on the wall pores and skirt of the cover, between the cover and the bottom of the cylinder with centering along its inner wall and with the possibility of displacement without distortions along the axis of the vibration isolator, a support is placed, which rests against the spring cover with a ball stop, a ball rolled into a shaft with the possibility of free rotation, and the outer surface - in the bottom of the cylinder of the coupling element with a small force created by a small axial interference of the spring, sharp edges of the elastic bushings, the cylindrical wall of the housing, the cover, the flange of the coupling element, as well as the junction The casing with its base and the flange with the clamping element are rounded with radii, the paws of the object, which it is placed on the vibration isolators, are screwed to the specified length with the lock nut, which, when the object is mounted on the vibration insulators, enter the central holes of the supporting platforms of the flanges of the coupling elements and squeeze it supports with a spherical stop and springs so that the paws are pressed against the supporting area of the flange of the coupling element, and the vibration-insulated object in this position is fixed with screws, under each head of which an elastic washer and a lock washer with a folding mustache are mounted, and the length of the finger and its threaded part are selected such that, by selecting the screw-in length of the finger, it would be possible to ensure that the unloading spring of each vibration isolator perceives the entire weight of the object attributable to this vibration isolator, or only given it share. 2. The large-capacity vibration isolator unloaded according to claim 1, characterized in that the elastic bushings are made by sequentially pressing the workpiece in radial and axial directions, and the degree of deformation of the workpiece in each of these operations - pressing phases is selected so that the plane of the coils of the spirals of the main mass of turns in the volume of the sleeve are inclined to the vertical axis of the vibrator at angles φ lying within 45 ° ≤φ≤α, where α is the angle equal to half the angle of the cone of the sleeve. 3. Vibration isolator heavy-duty unloaded according to claim 1 or 2, characterized in that its discharge spring is made of woven from three cores. 4. The heavy-duty vibration isolator unloaded according to claim 3, characterized in that an anti-shock pad made by axial pressing of high density metal-rubber material is fixed in its bottom 5. The heavy-duty vibration isolator unloaded according to claim 4, characterized in that it is made with cylindrical elastic bushings, and the angles of inclination of the plane of the turns to the vertical axis of the sleeve for the bulk of the turns of the material of the sleeve differ little from 45 °. 6. A large-capacity vibration isolator unloaded according to claim 5, characterized in that distance spacers are installed between the flange of the coupling element and the elastic sleeve and between the cover and the other elastic sleeve, with a central hole with a diameter equal to the diameter of the opening of the housing base, and the sharp edges of the spacers are rounded with radii. 7. The heavy-duty vibration isolator unloaded according to claim 6, characterized in that the spring cover in the unloaded condition of the vibration isolator by the force created by the axial interference of the unloading spring is pressed directly to the bottom of the coupling element cylinder, and there is a concentric gap between the cover and the cylinder wall, slightly smaller or equal to the course of the vibration isolator in radial directions. 8. The large-capacity vibration isolator unloaded according to claim 7, characterized in that the spring cover is centered on the cylinder wall of the coupling element and has the ability to move without jamming along the cylinder axis, and there is a concentric gap between the spring and cylinder wall slightly less than or equal to the course of the vibration isolator in radial directions.

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