RU238033U1 - Heat shrinkable insulating sleeve - Google Patents

Abstract

The utility model relates to cable accessories, in particular to devices for connecting low- and medium-voltage electrical cables and wires. The technical result consists in increasing the moisture resistance of connections of extended electrical wires during repeated bending. The technical result is achieved due to the fact that the heat-shrinkable insulating sleeve contains a tube 1 made of a heat-shrinkable material, which in the initial state has a uniform internal diameter A along its entire length. A central ring 3 made of tin-lead solder and two sealing rings 2 are installed inside the tube 1. Moreover, the sealing rings are installed symmetrically at a distance from its edges of at least 0.8 times the internal diameter A of the tube. 1 c.p. fil., 1 fig.

Description

The field of technology to which the utility model belongs

The utility model relates to cable fittings, in particular to devices for connecting low- and medium-voltage electrical cables and wires.

State of the art

A heat-shrinkable insulating sleeve containing a tube made of heat-shrinkable material is known in the art (Russian Patent 166201, published November 20, 2016). A drawback of this known tube is its insufficient protection of the connected wires during repeated bending.

The essence of the utility model

The utility model solves the problem of increasing the mechanical strength of electrical cable connections.

The achieved technical result consists in increasing the moisture resistance of the connections of extended electrical wires during repeated bending.

The stated technical result is achieved by a heat-shrinkable insulating sleeve comprising a tube made of heat-shrinkable material. Said tube has a uniform internal diameter along its length. Two sealing rings and a central ring of tin-lead solder are installed within said tube. Said sealing rings are installed symmetrically at a distance from the edges of said tube equal to at least 0.8 times the internal diameter of said tube. A distinctive feature of the utility model is the presence of two compression rings and a ring made of solder.

List of drawing figures

Fig. 1 shows a cross-section of the sleeve.

Implementation of a utility model

Improving the reliability and quality of electrical cable and wire connections is a pressing technical challenge, a particular example of which is the development of cable and wire extension tools. Extension involves connecting two cables or wires of the same size and design to increase their overall length. This challenge arises when installing long electrical lines, for example, in buildings or other extended structures.

When connecting identical cables or wires, i.e. when increasing their length, the connecting means must have a symmetrical design to ensure the same conditions of interaction between the sleeve and the parts being connected.

When laying electrical networks, cables are subject to mechanical stress. Cyclic bending stress at cable joints is particularly dangerous, as it creates gaps in the insulation that allow moisture to penetrate.

The heat-shrinkable insulating sleeve comprises a tube 1 made of heat-shrinkable material, initially having a uniform internal diameter A along its entire length, as shown in Fig. 1. Tube 1 is preferably made of fluoroplastic, such as F-2M fluoroplastic, which exhibits high strength, hardness (up to 90 MPa Brinell), does not yield under load, exhibits increased elasticity, and is resistant to abrasive wear and ultraviolet and ionizing radiation. Fluoroplastic is a non-flammable material that provides an operating temperature of up to 200 degrees Celsius.

Inside the tube 1, at a distance from its edges, two sealing rings 2 are symmetrically installed, made of a polymer composition, for example, of a polyolefin polymer composition.

The internal diameter A of tube 1 ranges from 3 mm to 8 mm, and the distance C between sealing rings 2 ranges from 8 to 30 mm, depending on the cross-sectional area of the cables or wires being connected. The overall length B of the sleeve ranges from 17 mm to 40 mm.

To ensure high bending strength of the extended cables or wires, it is advisable to ensure that the inner diameter A of the tube 1 is at least 0.5 mm larger than the inner diameter D of the sealing rings 2. This ratio ensures uniform compression of the sleeve across the surface of the cables or wires being connected.

A central ring 3 with an internal diameter E made of tin-lead solder additionally treated with flux is installed inside tube 1. POS-61 tin-lead solder, containing 61% tin, can be used as the solder material.

As shown in Fig. 1, tube 1 contains four free sections that are not in contact with sealing rings 2 and central ring 3. It is advisable to ensure that the lengths of the free sections of tube 1 are approximately the same, at least so that they differ from each other by no more than 20%. Such an arrangement will ensure the same conditions for crimping the connected parts of the cable along the entire length of the sleeve.

The utility model works as follows.

Before extending an electrical cable or wire, one of the parts to be connected is threaded through a heat-shrinkable insulating sleeve, after which the conductive cores of the parts are mechanically connected using any known method. The heat-shrinkable insulating sleeve is then moved to the connection point of the cables or wires, ensuring its symmetrical position relative to the connection point.

Heat shrink tube 1 is exposed to a heat flow with a temperature that ensures shrinkage of the material (350-400 degrees Celsius) and melting of the solder material of the central ring 3.

Thermal shrinkage reduces the tube's dimensions, with longitudinal compression being minimal compared to transverse compression. In cross-section, tube 1 can be compressed by a factor of 2 to 6. Thermal shrinkage increases the wall thickness of tube 1, creating a tight fit between its inner surface and the outer surface of the cables or wires being connected. Thus, in a single process step, the conductive cores of the cables being connected are welded and the connection is reliably insulated. By compressing the molten solder with tube 1, the solder is evenly distributed across the cables being connected, increasing the strength and reliability of the connection.

Maximum reliability and bending strength of the joints of extended cables or wires is achieved when the area where the heat-shrinkable insulating sleeve is applied has a uniform curvature. This is achieved by uniformly compressing the cables or wires being connected with the inner surface of the sleeve. By making the inner diameter D of the sealing rings 2 smaller than the inner diameter A of the tube 1, the cables being connected are compressed not only by the material of the tube 1, but also by the material of the sealing rings 2. If the inner diameter of the crimping rings 2 is equal to the inner diameter of the tube 1, the heat-shrink force may not be sufficient to tightly compress the cables being connected with the rings 2, leaving a gap between them. If the difference in inner diameters is too great, voids will form near the sealing rings 2 after the material has shrunk, meaning that the cables being connected will not have contact with the sleeve components in these areas.

It is advisable to ensure the distance from the edges of tube 1 to the sealing rings 2 is at least 0.8 times the internal diameter A of tube 1. With this ratio, after heat shrinkage, the end sections of tube 1 will ensure reliable compression of the surface of the cables being connected. With smaller values, the material of tube 1 may not be sufficient to firmly compress the cables being connected by the end sections of the sleeve.

When installing or using extended cables or wires, bending loads can occur at the connection points, causing gaps in the end sections of the sleeve, allowing moisture to penetrate. Sufficient tube material (1) at the end sections ensures a secure and durable connection between the cables being connected and the sleeve, along with a high level of insulation.

Claims (2)

1. A heat-shrinkable insulating sleeve containing a tube made of heat-shrinkable material, said tube having the same internal diameter along its length, two sealing rings and a central ring made of tin-lead solder are installed inside said tube, said sealing rings are installed symmetrically at a distance from the edges of said tube that is not less than 0.8 of the internal diameter of said tube. 2. The sleeve according to item 1, characterized in that the sealing rings are made of a polyolefin composition.