RU2803433C1 - Supporting vibration clamp - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: supporting clamps for suspending wires of overhead power lines. The supporting vibration-resistant clamp contains a shock absorber made of two parts put on the supported wire, a wire protector wound on the shock absorber, a power housing made of two halves installed around the protector and connected to each other by means of a threaded connections, as well as a suspension pivotally connected to the power housing. According to the invention, the suspension is made in the form of a bracket having a socket of a hinge-spherical connection with the pestle of the insulator rod, while coaxial pins with outer cylindrical surfaces are located at the open ends of the bracket. Each half is provided with a protrusion located on its outer surface. Blind grooves are made in the protrusions with the formation on the surface of the protrusion of non-closed coaxial internal cylindrical surfaces having power sections. The trunnions are located with the possibility of contact with their outer cylindrical surfaces with the power sections of the protrusions and are made with the possibility of bringing them into contact with the power sections of the protrusions by moving the bracket with the trunnions relative to the halves and inserting the trunnions into the grooves of the protrusions. In this case, the geometric axis of the coaxial trunnions crosses the supported wire, and the clamp is equipped with a lock-limiter that prevents the trunnions from leaving the grooves of the protrusions after the clamp is assembled.

EFFECT: facilitating the mounting of the clamp, increasing the reliability of the wire suspension with increased structural strength and vibration resistance.

4 cl, 5 dwg

Description

The invention relates to electrical engineering, in particular, to supporting clamps for hanging wires of overhead power lines.

Known is a supporting vibration-resistant clamp containing a shock absorber made of two parts put on the supported wire, a wire protector wound onto the shock absorber, a power housing made of two halves installed around the protector and connected to each other using a threaded connection, as well as a suspension , pivotally connected to the power housing (see RU2064723 C1, publ., 07.27.1996).

The disadvantages of the known clamp are insufficient ease of installation due to the large number of individual parts connected directly on the wire, while providing better strength, as well as vibration resistance due to the location of the hinge axis connecting the suspension with the body in the area of intersection of this axis with the supported wire.

The technical problem is to create a vibration-resistant clamp that has increased strength, reliability, vibration resistance and has a design that makes it easier to install the clamp by reducing the range of parts connected directly during installation on the wire.

The technical result is to facilitate the installation of the clamp, increase the reliability of wire suspension with increased structural strength and vibration resistance.

The problem is solved, and the technical result is achieved by the fact that the supporting vibration-resistant clamp contains a shock absorber made of two parts, put on the supported wire, a wire protector wound on the shock absorber, a power housing made of two halves mounted around the protector and connected to each other using a threaded connection, as well as a suspension hingedly connected to the power housing, while, according to the invention, the suspension is made in the form of a bracket having a socket of a hinged-spherical connection with the pestle of the insulator rod, while at the open ends of the bracket there are coaxial axles with outer cylindrical surfaces, with each body-half equipped with a protrusion located on its outer surface, blind grooves are made in the protrusions to form open coaxial internal cylindrical surfaces having power sections on the surface of the protrusion, the axles are located with the possibility of contact with their outer cylindrical surfaces with the power areas of the protrusions and are made with the possibility of bringing them into contact with the power sections of the protrusions by moving the bracket with the trunnions relative to the housing halves and inserting the trunnions into the grooves of the protrusions, while the geometric axis of the coaxial trunnions intersects the supported wire, and the clamp is equipped with a limiting lock that prevents the trunnions from leaving the grooves protrusions after assembly of the clamp.

The technical result is also achieved by the fact that the housing halves can be additionally connected to each other using a cylindrical hinge located along the supported wire and offset relative to it in the direction of the bracket socket, and the geometric axes of the threaded elements connecting the housing halves are crossed with the supported wire and installed with the side of the wire opposite to the location of the cylindrical hinge.

The technical result is also achieved by the fact that the lock-limiter can be made in the form of an element located between the housing halves, limiting the movement of the bracket in the direction opposite to the power sections of the protrusions.

The technical result is also achieved by the fact that the lock-limiter is equipped with limiters located with the possibility of contact with the surfaces of the trunnions opposite their surfaces contacting the power sections of the protrusions, as well as latches freely located in the recesses of the housing halves.

The invention is illustrated with the help of drawings.

In fig. 1 is a side view of a clamp assembly mounted on a supported wire;

In fig. 2 - the same top view in Fig. 1;

In fig. 3 - the same, cross section A-A in Fig. 1;

In fig. Figure 4 shows an isometric view of the body-half;

In fig. 5 - the same, view of the body-half with a limiting lock located in its recess.

The described supporting vibration-resistant clamp contains a shock absorber 1, made of two parts, put on the supported wire 2, a wire protector 3, wound on the shock absorber 1, a power housing made of two housing halves 4, installed around the protector 3 and connected to each other using threaded elements 5, as well as a suspension made in the form of a bracket 6, which is a single part, which is equipped with coaxial axles 7 with outer cylindrical surfaces located at the open ends of the bracket 6. The axles 7 face the inside of the bracket 6 towards one another. The bracket 6 is also equipped with a socket 8 for a hinged-spherical connection with the pestle of the insulator rod (not shown in the drawings). Each half body 4 is equipped with a protrusion 9 located on its outer surface. In the protrusions 9 there are blind grooves 10 with the formation on the surface of the protrusion 9 of open coaxial internal cylindrical surfaces 11 having power sections 12. The axles 7 are located with the possibility of contact with their outer cylindrical surfaces with the power sections 12 of the protrusions 9, and are made with the possibility of being brought into contact with the power sections 12 of the protrusions 9 by moving the bracket 6 with the trunnions 7 relative to the housing halves 4 and inserting the trunnions 7 into the grooves 10 of the protrusions 9. The power section 12 can be made in the form of an insert installed in the cylindrical surface 11 or made integral with it, for example, by modification of surface 11 in a limited area in order to achieve increased wear resistance and reduce friction at the point of contact of interacting cylindrical surfaces. Thus, with the help of axles 7 and protrusions 10, a cylindrical hinge connection of the bracket 6 with the housing halves 4 is formed. In this case, the cylindrical surfaces 11 of the protrusions 9 are made in such a way that the geometric axis 13 of the coaxial axles 7 intersects the supported wire 2. The clamp is equipped with a limit lock 14 , preventing the trunnions 7 from exiting the grooves 10 of the protrusions 9 after assembling the clamp.

The housing halves 4 can be additionally connected to each other using a cylindrical hinge 15 located along the supported wire 2 and offset relative to it in the direction of the socket 8 of the bracket 6. For example, the longitudinal axis of the hinge 15 is parallel to the wire 2 after installing a clamp on it. The specified hinge 15 can be made in the form of a threaded element tightened with a nut 16. In this case, the longitudinal geometric axes of the threaded elements 5 of the connection of the housing halves 4 are crossed with the supported wire 2 and installed on the side of the wire 2 opposite to the location of the cylindrical hinge 15.

The lock-limiter 14 can be made in the form of an element located between the housing halves that limits the movement of the bracket 6 in the direction opposite to the coaxial grooves 10 of the protrusions 9.

In this case, the lock-limiter 14 is equipped with limiters 17, located with the possibility of contact with the cylindrical surfaces of the trunnions 7, opposite their surfaces in contact with the power sections 12 of the surfaces 11, as well as latches 18, freely located in the recesses 19 of the groove 20, made in the housing halves 4. The groove 20 is made on the internal surfaces of the housing halves 4, which are in contact with each other after they are tightened with threaded connections 5. Such a lock-limiter 14 can be made in the form of a half-ring, the ends of which are limiters 17. In this case, the end surfaces 21 of the half-ring are in contact with the open cylindrical surfaces of the trunnions 7, located on the opposite side of such cylindrical surfaces of the trunnions 7, in contact with the power sections 12 of the surfaces 11 and thereby preventing the trunnions 7 from exiting the hinge connection of the bracket 6 with the housing halves 4. The latches 18 are made in the form of a flat protrusion , located in the transverse plane of the semiring, in its middle part.

The clamp is used to secure wires on overhead communication or power lines. The described clamp is mounted as follows. At the place where the clamp is mounted on wire 2, two halves of the shock absorber 1 are installed symmetrically, securing them with electrical tape. Apply a spiral of wire protector 3 to the fixed halves of the shock absorber 1, mounted on a wire 2, and wind each spiral of the protector 3 sequentially onto the assembled shock absorber 1. The body halves 4, pre-connected by a cylindrical hinge 15, a pin or a corresponding bolt with a nut, are installed on top of the shock absorber 1 with installed protector 3, by first moving the housing halves 4 apart around the axis of rotation of the hinge 15.

Install threaded elements 5, for example, bolts, into the corresponding holes of the housing halves 4 and screw nuts onto their ends, leaving a gap between the housing halves 4 in the lower part equal to 10-12 mm.

From the end of the housing halves 4 to their middle, move the bracket 6 along the wire 2 so that the trunnions 7 pass along the housing halves 4 to the grooves 10 of the protrusions 9. Then lift the bracket 6 up and insert the trunnions 7 into the grooves 10 on both sides until they contact cylindrical surfaces of the trunnions 7 with power sections 12 cylindrical surfaces 11 protrusions 9. In the previously left gap between the housing halves 4, a lock-limiter 14 is inserted, placing its latch 18 into the recess 19 of the housing halves 4. With this installation, the lock-limiter 14 is located like this that its limiters 17 with their end surfaces 21 could contact the cylindrical surfaces of the trunnions 7, open at the bottom. Then the assembled assembly is connected to the elements of the insulating suspension (not shown in the drawings) by connecting the socket 8 to the pestle of the suspension, after which the specified assembly is transferred to the locking position.

The use of the described clamp allows you to reduce the loads on wire 2 that arise during operation, namely, from dancing and vibration of the wire, swinging under the influence of wind and ice loads. Contact between wire 2 and the supporting clamp occurs through rubber shock absorber 1, which does not wear out the wire (it does not become abraded or worn out). Wire protector 3 fastens the halves of shock absorber 1 to wire 2 and further reduces vibration loads on it. In addition, the axis 13 of the hinged attachment of the suspension to the housing halves 4 approximately perpendicularly intersects the longitudinal axis of the wire 2 along the median transverse plane of the housing halves 4 of the clamp, which has a positive effect on the distribution of loads on the clamp and wire.

Making the suspension from one piece in the form of a bracket 8 increases the strength and reliability of the fastening. At the same time, “unnecessary” operations of connecting parts of the suspension at height using small parts are eliminated, which simplifies the installation of an assembly that obviously has an increased range of parts due to the use of the necessary vibration protection elements.

However, using a one-piece suspension requires non-standard methods for assembling it. With this assembly, the trunnions 7 are inserted into the grooves 10 from their open side until they come into contact with the power sections 12 of the protrusions 9. That is, on the side where the trunnions 7 are inserted into the grooves 10, there is no locking surface that prevents the trunnions 7 from leaving the groove 10. The function of such locking is performed by limiters 17 lock-limiter 14, which simply fits into the recess 19 of the groove 20, made in one or both housing halves 4. Moreover, at the time of installation, the nuts are already screwed onto the ends of the threaded elements 5, which guarantees the preservation of the integrity of the assembled unit during the inclusion of a small part in it . That is, to perform the operation of locking the trunnions 7, no special tool or additional fasteners are required, which greatly simplifies the installation of the unit at height. After placing the lock-limiter 14 through the gap left between the housing halves 4, the latter are tightened by threaded elements 5. In this case, the housing halves 4 are pre-assembled by connecting them using a cylindrical hinge 15, around which the housing halves 4 can rotate. This pre-assembly also makes it easier to mount the unit at height.

Thus, the design of the described vibration-resistant clamp is relatively simple, strong and reliable, despite the use of the necessary vibration protection elements in the assembly. In addition, its installation does not require assistants or highly qualified specialists due to the significant simplification of installation at height.

Claims (4)

1. A supporting vibration-resistant clamp containing a shock absorber made of two parts put on the supported wire, a wire protector wound onto the shock absorber, a power housing made of two halves mounted around the protector and interconnected using a threaded connection, and a suspension hingedly connected to the power housing, characterized in that the suspension is made in the form of a bracket having a socket of a hinged-spherical connection with the pestle of the insulator rod, while at the open ends of the bracket there are coaxial axles with outer cylindrical surfaces, and each half body is equipped with a protrusion located on its outer surface, blind grooves are made in the protrusions with the formation on the surface of the protrusion of open coaxial internal cylindrical surfaces having power sections, the axles are located with the possibility of contact with their outer cylindrical surfaces with the power sections of the protrusions and are configured to bring them into contact with power sections of the protrusions by moving the bracket with the trunnions relative to the housing halves and inserting the trunnions into the grooves of the protrusions, while the geometric axis of the coaxial trunnions intersects the supported wire, and the clamp is equipped with a limiting lock that prevents the trunnions from leaving the grooves of the protrusions after assembling the clamp. 2. The clamp according to claim 1, characterized in that the housing halves are additionally connected to each other using a cylindrical hinge located along the supported wire and offset relative to it in the direction of the bracket socket, and the geometric axes of the threaded elements connecting the housing halves are crossed with the supported wire and installed on the side of the wire opposite to the location of the cylindrical hinge. 3. The clamp according to claim 1, characterized in that the lock-limiter is made in the form of an element located between the housing halves that limits the movement of the bracket in the direction opposite to the power sections of the protrusions. 4. The clamp according to claim 3, characterized in that the limiter lock is equipped with limiters located with the possibility of contact with the surfaces of the trunnions opposite their surfaces contacting the power areas of the protrusions of the housing halves, as well as clamps freely located in the recesses of the groove of the housing halves .