RU2212742C2 - Support for fastening long-measuring parts - Google Patents

Abstract

FIELD: hardware such as supports, clips, clamps, and the like for suspending long-measuring parts assembled in systems. SUBSTANCE: support designed for suspending long-measuring parts such as cables, pipes, and the like assembled in systems for conveying signals and materials over long distances has flexible insert secured in case of semi-ring members of supporting clamp that has bushing and longitudinal corrugated cones. Flexible insert is made of material whose elastic stiffness is higher and rigidity is lower than those of long-measuring part material; flexible insert has slit in its top part whose width depends on its elastic stiffness and on its pushing angle. Insert has longitudinal central channel to receive long-measuring part. Flexible insert has junction flanges on side of semi-ring members of supporting clamp case; insert bushing is provided with locating member made in the form of cone with transverse pushing collar that locks flexible insert in semi-ring member of case to prevent its longitudinal displacement. EFFECT: improved protection of long-measuring parts against bending moments; improved protection of supports. 9 cl, 4 dwg

Description

 The invention relates to objects such as supports, clamps, clamps and the like, designed to suspend long objects such as cable, pipe and the like, which are mounted in systems that transmit signals or substances over long distances. In particular, a cable mounted on ground supports, such as poles of an electric contact network and automatic blocking of railway lines, can be considered as a long object. The cable can be either an optical, self-supporting communication cable, or high-voltage electric cables. All types of cables can be mounted on poles of power lines, as well as on special supports, as well as on the surfaces of other load-bearing elements, and the required distance between the supports is determined by the technical and operational requirements for transmission lines.

 Known hose clamp [1] having a conical inner surface and a spiral spring with longitudinal grooves. However, the invention does not solve the problem of creating a tapped slip force.

 A support clamp of a spiral type is known for attaching fiber optic cables of communication lines or wires of overhead power lines [2], comprising a cable fixing mechanism in the form of levers resting on a pressure plate, a spiral tread and rubber bushings made in the form of cylinders tapering along the conical surface make ends. This invention solves the issue of adjusting the cable termination over a wide range of strengths and protects the cable from damage during pulling, however, it does not protect the cable from damage due to bending moments and / or transverse loads and does not solve the problem of increasing the protection of ground power supports from buckling due to for lateral loads. In addition, it is designed for loads far exceeding permissible, and is expensive and time-consuming.

 The closest in technical essence to the claimed invention is a support for fastening long objects such as cable [3], consisting of a cylindrical sleeve in the form of two semi-ring elements connected by an axis, each of which has a sash and a tie-rod with flat inner surfaces, an elastic insert and fasteners consisting of coupling and fixing elements. The specified invention allows to prevent the possibility of kink of sagging objects such as a cable on the line of the edges of the sleeves, but not guaranteed, since the cable has the ability, at maximum extreme loads, to fall into the gap between the elastic half rings and be damaged due to its contact with the metal parts of the clamp housing. In addition, under transverse loads and when exposed to bending moments, it does not provide a calibrated axial force, which ensures cable slippage under loads more than permissible. Thus, the cable is not protected from damage as a result of bending moments and / or transverse loads and the increased protection of ground power supports from stability loss due to transverse loads.

 With mounted networks in which the cable is fixed to the power supports with a certain distance between the supports, the cable is subjected to axial load, which in the conditions of cable slack leads to the fact that transverse loads and bending moments act on the cable, and the horizontal load from uneven the distribution of axial loads in a cable fixed in many supports on which, for example, an electrical contact network is mounted. In this case, the amount of cable slack between the supports depends both on the specified technical characteristics of the network, for example, the distance between the supports, and on additional external loads, for example, on icing of the cable, wind load, and the impact of weather conditions (rain, snow). At large sagging angles, the probability of cable bending by a radius smaller than the permissible one significantly increases due to large transverse loads and bending moment, as a result of which damage can occur. In addition, cable bending may occur when it abuts against the metal parts of the clamp, which will also damage the cable. Increased loads on the cable create a horizontal force on the support, leading to its loosening and loss of stability. All of the listed operating conditions of the networks require providing a calculated, tared pulling force of the cable, which makes it possible to equalize the loads both on the cable itself and on the network supports.

 Thus, it is necessary to exclude the deformation of the cable as a result of its crushing and / or cutting. To equalize the network loads between the cable clamping points and the supports, it is necessary to provide the specified pulling force of the cable in the clamp, and for this to provide a calibrated cable squeezing force using the clamp. Thus, it is necessary to improve the operating conditions of the network in conditions of insufficient strength of long objects and the stability of supports from the effects of loads due to the dead weight of the object and external influences. External influences are caused by thermal expansion (compression) of the cable, weather conditions - humidity, snow sticking, icing, wind load. In addition, when the bending moment is greater than the permissible limit, it is necessary to provide an emphasis that limits further bending of the cable and at the same time ensures its slippage.

 The technical result of the claimed invention is to increase the security of long objects from damage as a result of bending moments and / or transverse loads and to increase the security of supports holding the network of long objects from stability loss due to the impact of transverse loads on them.

The drawings schematically depict:
Figure 1 - support for mounting a long object mounted in a clip, a longitudinal section;
Figure 2 - support for mounting a long object mounted in a clamp, a cross section;
Figure 3 - fragment of the corrugated cone, the most curved position;
Figure 4 is a longitudinal section of a sleeve of an elastic element fragment.

 The support for mounting lengthy objects contains an elastic insert 1 fixed in the housing 2 of the semicircular elements 4 of the supporting clip, the elastic insert 1 consists of a sleeve 3 and longitudinal corrugated cones 5. The elastic insert 1 is made of a material having an elastic coefficient greater and less rigidity than the material of the long object 7 is provided with a slit-like cut 8 in the upper part, the width of which is determined depending on the coefficient of elasticity of the material of the elastic insert and the squeezing angle of the elastic insert ysha 1. The insert has a central longitudinal channel 9 for laying a long object 7. On the side of the semi-ring elements 4 of the support clamp housing 2, the elastic insert 1 has connecting flanges 10, while the sleeve 3 is provided with a mounting element 11, which is made in the form of a cone 12 with a squeezing transverse collar 13, fixing the elastic insert 1 in the semicircular element 4 of the housing 2 from longitudinal displacement.

The elastic insert is also equipped with power protrusions 14, symmetrically located in the diametrical plane on both sides of the longitudinal channel 9, creating the calculated compressive force of the long object 7 due to the height of the protrusion, the magnitude of which is calibrated by the calculated magnitude of the compressive force. In this case, the calculated compressive force and the total length of the surfaces L of the protrusions 14 in contact with the long object 7 provide the calculated pull force (axial) of the long object 7. The central longitudinal channel 9 of the sleeve 3 forms a hole whose diameter d is larger than the diameter d _{1 of the} long object a value depending on the allowable amount of deformation of the elastic liner when it is bent under the action of transverse loads, and which is designed so that, as a result of deformation of the sleeve, the force squeezing a long object remained within the calculated values.

The elastic insert 1 is also equipped with longitudinal corrugated cones 5, which protrude from the body of the semicircular elements, the outer side of the elastic parts of each of the corrugated cones made in the form of corrugations with a height h, step B of the protrusions 15 and the distance between them, limiting the maximum turn of the corrugated cone to a value not less than the minimum allowable bending radius R of a long object, and the protrusions 15 of the corrugation create an additional force element 16 that prevents bending (bending is greater, than the permissible minimum radius R) of the long object 7, which protects the long object from destruction, with a maximum turn of the corrugated cone. For example, an elastic liner is made of a mixture of rubbers. In addition, the elastic liner may be provided with mounting elements 12 more than one. In an elastic insert, for example, the central longitudinal channel 9 of the sleeve 3 is provided with vertical power projections 14. Or, for example, the central longitudinal channel of the sleeve has a hole shape, the diameter d of which is larger than the diameter of the long object d ₁ by an amount depending on the allowable amount of deformation of the elastic insert when its bending under the action of transverse loads, and is designed so that as a result of deformation of the sleeve 3, the compressive force of the long object remains constant or increases, asymptotically approaching the maximum calculated value.

 In particular, they ensure that the deformation of the central part of the liner does not exceed the permissible one by selecting the outer corner A of the longitudinal corrugated cone 5 of the elastic liner 1. The connecting flanges 10 of the elastic liner are made, for example, equal in diameter to the outer diameter of the power collars 16 half-ring elements 4 of the housing 2 and equipped with reinforcing elements repeating the shape of the power elements 17 of the semicircular element 4 of the housing 2. At the extreme protrusions of the corrugated cones of the elastic insert, there may be lozhena annular sample 18 under the retaining ring 19.

 Support for mounting long objects works as follows.

 To mount the supporting clip, the elastic insert is fixed with the help of the installation element, for which purpose the insert lock is threaded into the installation element of the sash with effort. Due to the deformation of the elastic retainer during threading and further retention due to its elasticity, the elastic insert is fixed from shearing. The rear semicircular element is fixed by a fastening element to the mounting surface, for example to a support. The front flap leans back at an angle equal to or less than 90 degrees, providing a horizontal plane with a longitudinal groove to maintain the cable at a horizontal height. At the same time, the front sash is supported. The elastic insert extends through the slot to the spin angle, the cable is inserted into the elastic insert. After that, the front sash is rotated around the axis and tightened with the help of tightening bolts until it contacts the inner surface of the rear sash and the inner surface of the front sash.

 In the particular case, the back flap abuts against the front one by means of calibration sleeves, which allow taring the force of the tightened sleeve, and through it the sliding force of the cable.

 After that, the supporting clamp is fastened with fasteners. As a result of the transfer of horizontal force, which is a component of the pulling force to the supports, it is possible to obtain lateral loads on the support within the specified values and the absence of transfer of loads at exceeded design forces due to cable slippage and load redistribution between the network supports, which increases the security of the supports.

 In addition, during operation, under the influence of transverse loads on the edges of the elastic element, the inner surface of the elastic liner may experience deformation within the gaps between the inner diameter and the protrusions. However, due to the calculated value of the total length of the protrusions, deformations are not transmitted to the cable due to the existing gap between the inner diameter of the sleeve and the cable, which provides freedom for deformation of the sleeve without transmitting the deformation to the cable.

 The inventive support for attaching long objects makes it possible to increase the security of long objects from damage due to bending moments and / or transverse loads and to increase the security of the supports holding the network of long objects from stability loss due to transverse loads.

 The support can also be used in the case of both communication lines and power transmission lines.

Sources of information
1. Copyright certificate for the invention of the Russian Federation 1167398, IPC 4 F 16 L 33/02.

 2. Patent for the invention of the Russian Federation 2055433, IPC 6 H 02 G 7/05.

 3. Patent for the invention of the Russian Federation 2146785, IPC 7 F 16 L 3/10.

Claims (9)

 1. Support for mounting long objects, containing an elastic liner fixed in the housing of the semicircular elements of the clamping support, characterized in that the elastic liner consists of a sleeve and longitudinal corrugated cones, made of a material having an elastic coefficient greater and stiffness less than the material of a long object is equipped with a slit-like cut in the upper part, the width of which is determined depending on the coefficient of elasticity of the material of the elastic insert and the spin angle of the elastic insert , the central longitudinal channel for laying a long object, from the side of the semicircular elements of the housing of the supporting clamp, the elastic insert has connecting flanges, and the sleeve is equipped with a mounting element, which is made in the form of a cone with a squeezing transverse collar fixing the elastic insert in the semicircular element of the housing from longitudinal displacement, and power protrusions symmetrically located in the diametrical plane on both sides of the longitudinal channel, creating a calculated compressive force d linear object due to the height of the protrusion, the magnitude of which is calibrated by the calculated value of the squeezing force, while the calculated squeezing force and the total length of the surfaces of the protrusions in contact with the long-sized object, provides the estimated axial pulling force of the long-sized object, while the Central longitudinal channel of the sleeve forms a hole, the diameter of which is larger than the diameter of the lengthy object by an amount depending on the allowable amount of deformation of the elastic liner when it is bent under the action of transverse loads, and which is designed so that as a result of the deformation of the sleeve, the compressive force of the long object remains within the calculated values, and the longitudinal corrugated cones protrude from the body of the semicircular elements, and the outer side of the elastic parts of each of the corrugated cones is made in the form of corrugations with the height, pitch of the protrusions and the distance between them, providing a limitation of the maximum turn of the corrugated cone to a value not less than the minimum acceptable radius of bending the elongated object, and the projections of the corrugation creating additional strength member preventing inflection elongated object with a maximum spread of corrugated cone.  2. Support for mounting long objects according to claim 1, characterized in that the elastic insert is made of a mixture of rubbers.  3. Support for mounting long objects according to claim 1, characterized in that the elastic insert is provided with mounting elements of more than one.  4. Support for mounting long objects according to claim 1, characterized in that the power protrusions of the central channel of the sleeve are made vertical.  5. Support for mounting long objects according to claim 1, characterized in that the central longitudinal channel of the sleeve has a hole shape, the diameter of which is larger than the diameter of the long object by an amount depending on the allowable amount of deformation of the elastic liner when bending under transverse loads, and calculated so that as a result of the deformation of the sleeve, the compression force of the long object remains constant or increases, asymptotically approaching the maximum allowable design value.  6. Support for mounting lengthy objects according to claim 1, characterized in that they provide a strain value of the central part of the liner that does not exceed the allowable due to the selection of the outer angle of the longitudinal corrugated cone of the elastic liner.  7. Support for mounting long objects according to claim 1, characterized in that the connecting flanges of the elastic insert are made equal in diameter to the outer diameter of the power collars of the semicircular elements of the housing and are equipped with reinforcing elements.  8. Support for fastening long objects according to claim 7, characterized in that the connecting flanges are made equal in diameter to the outer diameter of the power collars of the semicircular body elements and have a reinforcing element that repeats the shape of the power elements of the semicircular body element.  9. Support for mounting long objects according to claim 1, characterized in that at the extreme protrusions of the corrugated cones of the elastic insert there is an annular selection under the retaining ring.

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