RU2683001C1 - Unit for testing a cable - Google Patents

Abstract

FIELD: testing equipment.SUBSTANCE: invention can be used to test a power cable of power mining equipment and machinery, mainly self-propelled cars, cleaning and tunneling machines. Unit includes a carriage mounted on rails mounted on the base. On two opposite sides of the carriage supports are mounted. For reciprocating movement of the carriage along the guides a two-strand rope drive is installed, consisting of a rope fixed on pulleys connected to an electromechanical drive on one of the supports, and a turntable mounted on the second support. Cable under test is fixed at one end to the support, and to the other – directly to the carriage. When testing, the cable can be placed in a cable laying machine, which is laid on the base and at one end is also attached to the support, and at the other to the carriage. Without a cable laying machine, the end of the cable is fixed on the support through a tension unit, made in the form of two consecutive rollers connected to a controlled pneumatic cylinder. During the movement of the carriage with a fixed end of the cable, the cable is subjected to dragging, curving in an arbitrary shape, is subjected to torsion with the formation of a different shape of the loop, strained and stretched.EFFECT: ability to simulate the actual operating conditions and with a high degree of reliability to assess the mechanical strength of the cable and to identify defects that occur during operation.3 cl, 2 dwg

Description

The invention relates to testing equipment, and more particularly, to devices for testing a flexible cable for operational loads, and can be used for testing for bending, bending, torsion and tension of a power cable designed to power mine equipment and machines, mainly self-propelled cars, sewage treatment plants and roadheaders.

A well-known stand for testing the mechanical strength of flexible cables (GOST IEC 60227-2-2012. Part 2. Test methods. P. 3.1. Flexibility test. Figure 1). The stand contains a carriage, a carriage control system and four metal rollers for each cable size to be tested. Two of the four rollers are made of the same size and mounted on the carriage. The other two rollers are mounted stationary at the ends of the stand and may have a diameter different from the diameter of the rollers mounted on the carriage. The rollers have a groove: semicircular for round cables or rectangular for flat cables. All four rollers are installed so that the cable is between them in a horizontal position. The carriage makes a cyclic (reciprocating) movement. Cable tension is created using weights and holding clamps located at both ends of the stand. The carriage is controlled smoothly and without jerking. The design of the stand fixes the damage received during the test and stops the test when the current is interrupted, a short circuit between the conductors or between the sample and the rollers. However, the specified design of the stand does not allow to assess the influence of kinks, bends and twists that occur during operation of the power cable.

A known stand for testing resistance to repeated bending of cables, wires and cords intended for connecting movable electrical installations (GOST 12182.1-80. Cables, wires and cords. Methods of checking resistance to repeated bending through a system of rollers). The stand contains a carriage with interchangeable rollers, a mechanism for reciprocating movement of the carriage in a section of at least 1 m long with a speed of (0.35 ± 0.05) m / s, a tension device or a set of weights and clamps that limit the movement of the sample. Replaceable rollers lie in the same plane, and their axes are parallel to each other and to the axis of the tension and drive rollers. The tests consist in moving the rollers along the specimen when the carriage moves from its extreme starting position, first in one direction, and then in the opposite direction at a given tension. The roller system sets the pattern of deformation of the sample and the number of bends. The stand allows you to test the mechanical strength of the cable, to identify during the test damage to the sheath, insulation, shield and other structural elements of the cable. However, this design of the stand, as well as the stand according to GOST IEC 60227-2-2012, does not allow us to evaluate the mechanical strength of the cable with different forms of kinks, bends, twists and strains that occur during the operation of mine cables for powering self-propelled cars, shearers and roadheaders.

A device is known for testing cables for repeated kinks according to ed. USSR for the invention No. 1430812, IPC G01N 3/20, publ. 10.15.88, which is taken as a prototype of the claimed installation. The prototype device contains a base on which guides are mounted with a carriage mounted on them, kinematically connected with a reciprocating traction drive, two brackets (supports) mounted on the base from two opposite sides of the carriage, one of them directly on the base, and the other through the guides. The drive of the reciprocating movement of the carriage is made in the form of a gear sector, connected through a gear wheel fixed to the shaft with a traction wheel. The latter is connected to the carriage by means of an extension cord covering the traction wheel and rollers fixed to the supports. Clips are used to secure the ends of the rope. One clip, passive, is mounted on a support mounted on the base. The second clamp, active, is mounted on rails and connected through a dynamometer to a tensioning mechanism. An inflection unit is installed on the carriage. The inflection unit is made in the form of two blocks. Each block contains the same number of interchangeable rollers with grooves mounted rotatably on the carriage. The rollers in each block are mounted parallel and coaxial, and their axes are located in the same plane perpendicular to the axis of the tensioning mechanism. The rollers of different blocks are installed at a given angle to each other. When moving the carriage, the cable sequentially bends along the entire length around the rollers of both blocks, without undergoing twisting deformation during the transition from roller to roller. The installation of the rollers of different blocks at an angle to each other with the alignment of the rollers in each block provides an increase in the angle of coverage of the rollers with the test cable. The prototype device does not allow reliable results for power cables used to power self-propelled cars, shearers and roadheaders, which during operation are subject to repeated bends of various shapes, tensile forces, tension and twisting.

The technical problem solved by the invention is to bring the test conditions of the cable for powering the mine equipment and machines as close as possible to the conditions of its operation and thereby increase the reliability of the results during testing.

In the test process, the inventive installation provides reciprocating movement of the cable by drawing it and provides as a result of such movement the cable tension under the action of tensile load, as well as kinks, twists and bends with a different loop shape.

The specified technical result, providing a solution to the problem, is achieved as follows.

The inventive installation, as the prototype device, contains guides mounted on the base, a carriage mounted on the guides with the possibility of reciprocating movement, a traction drive for moving the carriage, two supports mounted on two opposite sides of the carriage, and means for attaching the ends of the cable , and one of them is supported.

In contrast to the prototype, a two-strand rope drive was used to move the carriage, consisting of a rope mounted on pulleys connected to an electromechanical drive on one of the supports and a rotary roller mounted on the second support.

The carriage is fixed on the rope. The difference is also that the means for attaching the second end of the cable are mounted directly on the carriage.

In one of the special cases, for connecting the end of the cable fixed on the support to the carriage, an additional cable tension unit is installed, made in the form of two successive rollers connected to a controlled pneumatic cylinder.

To accommodate the cable under test, the installation, in another special case of execution, may additionally include a track cable layer laid on the base and fixed at one end to one of the supports, and the other to the carriage.

The carriage moves freely along the rope to a predetermined position and returns to its original position. When moving the carriage with the cable end attached, the cable is drawn. In the process of drawing, it bends in an arbitrary form, undergoes torsion with

the formation of a different loop shape, for example in the form of 00 or S-shaped,

stretched and stretched. Such test conditions simulate real operating conditions and allow a high degree of reliability to assess the mechanical strength of the cable and identify defects that occur during operation.

The set of essential features characterizing the installation claimed as an invention is not identified from the prior art, which confirms the novelty of the invention.

Despite its simplicity, the invention does not explicitly follow from the prior art. No information has been found in the prior art about cable test installations in which the fastening of the cable end would be directly on the movable carriage. There is also no information about the technical result when testing the cable, which is provided by the claimed invention, and consists in drawing and formation in the process of drawing the cable of various shapes of bends, twists, tensions and stretchings. The above confirms the compliance of the invention with the condition of "inventive step".

The invention is illustrated by drawings.

In FIG. 1 shows a general view of the installation with a cable tension unit.

In FIG. 2 is a general view of the installation with a track stacker.

The installation (Fig. 1) contains a carriage 1 mounted on rails 2 made in the form of rails. To fix the end of the cable 3 on the carriage 1 are three horizontally mounted stationary rollers. To move the carriage 1, a two-strand rope 4. serves. The ends of the rope 4 are mounted on pulleys connected to an electromechanical drive 5 mounted on the support 6. The rotary roller for the rope 4 is mounted on the support 7. The carriage 1 is equipped with rotating rollers for movement along the guide rails. The second end of the cable 3 is fixed to the support 7. The installation contains a tension unit 8 (Fig. 1) The tension unit 8 contains two sequentially connected rollers 9, 10. The roller 10 is connected to a controlled pneumatic cylinder 11. In this case (Fig. 1) the end of the cable 3 fixed on the support 7 through the tension unit 8. The cable 3 can be laid in the track cable layer 12 (Fig. 2), with one end mounted on one of oop, for example 6, and the other on the carriage 1.

Installation works as follows.

One end of the cable 3 is fixed on the carriage 1, the other on the support 7 (Fig. 1) through the tension unit 8, passing the cable 3 between the rollers 9, 10.

The drive 5 is turned on, and the carriage 1 with the fixed sample of the cable 3 begins to make reciprocating movements along the rails 2 to a predetermined position. When the cable 3 is drawn, bends and twists occur with the formation of a different loop shape and the subsequent reproduction of the tensile load when the tension unit 8 is turned on at a certain moment. The test cycle is repeated. As a result of tests, possible defects and design flaws of the cable that arise during its operation are identified. In the presence of the track cable layer 12 (Fig. 2), one end thereof is fixed on the support 6, the second on the carriage 1. The cable layer 12 lies freely on the base.

The installation works similarly to that described above and provides reciprocating movement of the carriage 1 with the track stacker 12 in which the cable 3 is laid in each test cycle. When the carriage 1 is moved, a cable stacker loop is formed, and when the carriage 1 reaches its extreme position, the track stacker 12 is straightened , flips from one direction to another. When moving in the opposite direction, the track stacker 12 is again laid in a loop and stretched to its original starting position. Thus, the operating conditions of mine cables are simulated when feeding shearers and roadheaders, creating deformation (bends) of the cable during drawing. During the tests, possible defects and deficiencies in the design of the cable laid in the cable layer, its mechanical strength are also revealed.

Claims (3)

1. Installation for testing a cable containing guides mounted on the base, a carriage mounted on the guides with the possibility of reciprocating movement, a traction drive for moving the carriage, two supports mounted on the base from two opposite sides of the carriage, and means for attaching the ends of the cable moreover, one of them is on a support, characterized in that for moving the carriage a two-strand rope drive is used, consisting of a rope mounted on pulleys connected to an electromechanical Odom on one of the supports and the rotary roller mounted on the second support, wherein the carriage is fastened to the rope, in addition, means for securing the second end of the cable are mounted directly on the carriage. 2. Installation for testing the cable according to claim 1, characterized in that for connecting the end of the cable fixed to the support with the carriage, an additional cable tensioning unit is made in the form of two successive rollers connected to a controlled pneumatic cylinder. 3. Installation for testing the cable according to claim 1, characterized in that it further comprises a track cable layer for placing the test cable, laid on the base and fixed at one end to one of the supports, and the other to the carriage.

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