RU17747U1 - CONNECTOR OF A MULTI-WATER DEEP WATER CABLE WITH SMALL CABLES - Google Patents

Description

CONNECTOR OF A MULTI-WATER DEEP-WATER CABLE WITH SMALL-CABLE CABLES.

The utility model relates to electrical engineering, namely, to sealed connectors of a deep-sea multi-core cable with small-core cables, which operate for a long time in marine conditions at high hydrostatic pressures. The utility model can also be used in the national economy for underwater and surface devices with multi-element lines of electrical communications of high reliability for long-term work in afessive environments.

Currently, connectors for multicore cables with multicore cables in a monolithic rubber casing are widespread because of their resistance to: high hydrostatic pressures in deep water conditions, aggressive liquid and gaseous media, mechanical stress, shock and vibration (see, for example, 1, 2).

In terms of features, the closest to the proposed utility model is a multi-core deep-sea cable connector with small-core cables or wires, described in 1 Fig. 19 p. 39.

The prototype connector contains insulated soldered nodes of the conductive conductors of a multicore deep-sea cable with conductive conductors of low-voltage cables, housed in a monolithic housing made of oil-and-petrol-resistant rubber made by high-temperature vulcanization directly at each node of the conductors connection. The disadvantage of this design of the connector is the high complexity of manufacturing. With a large cable core, the pressing time is 12 hours or more. In addition, the use of high-temperature vulcanization twice: when isolating the core connections and manufacturing an oil and petrol resistant rubber mass at a vulcanization temperature of -170 ° C close to the melting point of the solder, it reduces the quality of the electrical connection of the wires due to the possibility of damage to the core connection node itself. At the same time, the transient electrical connection of the cores increases, the probability of spontaneous violation of the electrical contact at the connection node, for example, during vibrations.

IPC H01B7 / 14, H02G15 / 08

The objective of the utility model is to reduce the time and laboriousness of manufacturing a connector, improve the quality of insulation of conductors, as well as the safety of cable sheaths and soldered nodes for connecting conductive conductors of connected cables during their manufacture.

To solve this problem, new signs are introduced into the well-known connector of a multi-core deep-sea cable with small-core cables, containing insulated solder joints of conductive conductors of connected cables, housed in a monolithic housing made of oil-resistant rubber, namely: conductive conductors joints are installed in through cylindrical openings of a multi-seat insulator made from high temperature insulating rubber, and the vulcanization temperature of oil and petrol resistant rubber is monolithic about the case below the melting temperature of the insulation of the conductors and the hose shell of the connected cables and soldered joints of conductive conductors.

The laboriousness of installation and press operations is minimized when the multicore cables are the output cables of the underwater device and are connected to the cores of the multicore cable within the rubber array of the connector.

The technical effect of using the utility model is to reduce the complexity and time of manufacturing the connector, as well as the safety of the hose shells and soldered joints of the cores, which ultimately leads to increased reliability of the claimed connector. This is achieved by using a multi-seat insulator made of high temperature rubber. This eliminates the need for isolation by hot vulcanization of each node connecting conductive conductors of the connected cables. When using oil and petrol resistant low temperature rubber mixtures for a monolithic body, a sparing mode is created for (yolulation of hose shells and soldered nodes of conductive core connections.

The essence of the utility model is illustrated in FIG. 1, FIG. 2 and FIG. 3, where FIG. 1 and FIG. 2 show two projections of a multi-core deep-sea cable connector with multi-core cables, and in FIG. 3 a sectional view of a multi-seat insulator.

2x1.5. Each core 3 of a multi-core cable 1 is connected to one core 4 of a two-core cable 2. A node for connecting conductive wires 5 is placed in a through cylindrical channel 6 of a multi-seat insulator 7 made of high-temperature insulating rubber. As this rubber, for example, C-572 grade rubber can be used, the vulcanization temperature of which is ITOH-ISO C. A multi-seat insulator 7 with connection nodes 5 of cores 3 and 4 is placed in an array of monolithic casing 8 of the connector. The monolithic body 8 is made of LTI-34 grade low-temperature rubber whose vulcanization temperature is in the range of 7080 ° C, which is significantly lower than the soldering temperature (t 185 190 ° C), as well as the maximum allowable temperatures for insulation of the cores and the cable sheath. Multicore cables can be directly output cables of a deep-sea instrument. The number of connections may be different, and is determined by the number of cores of a multicore cable.

The claimed connector is made as follows. First, the conductors of the connected cables 3, 4 are removed from the hose sheath, these conductors are shortened at the location of the connection nodes of the conductive conductors 5 in the connector array, the conductive conductors are freed from insulation -10 mm from the end of the conductor, the strands of conductive conductors are developed and stripped, the original winding is restored and produce tinning POS-40. A multi-seat rubber insulator 7 is previously put on the cores 3, pre-made from a high-temperature insulating rubber compound, and is shifted from the location of the connection points of the conductive cores (vulcanization time of the multi-seat insulator 30 minutes). Connect conductive wires. A multi-seat insulator is pushed onto the nodes of the connection of conductive conductors 5. The surfaces of the hose shells are roughened, wrapped with an oil-and-petrol-resistant low-temperature rubber mixture 8, the entire package of joints and the connector are sealed by vulcanization at a temperature of 70-80 ° C.

Since the time-consuming operation of isolating each node of the connections of conductive wires by vulcanization is eliminated (it takes min. To isolate one connection of conductive wires 1 p. 38), the complexity of manufacturing the connector is reduced. Sealing by vulcanization at temperature provides a gentle mode for insulation of cores, cable sheaths and soldered joints of conductive cores (the melting point of solder is 185-190 ° C). At the same time, the quality is significantly improved and the reliability of the connectors is increased. Based on the foregoing, consider that a utility model solves the problem. 4

Literature.

1 - A.G. Rabinovich, L.A. Rubanov “Technology for the production of sonar equipment. Publishing house "Shipbuilding Leninfad, 1973 2 - Certificate of authorship No. 365763, USSR published in 1973. Bulletin No. 6 “Terminator of a deep-sea cable.

Claims (2)

1. Connector of a multicore deep-sea cable with multicore cables, containing insulated solder joints of conductive conductors of a multicore deep-sea cable with conductive veins of low-voltage cables, housed in a monolithic housing made of oil and petrol resistant rubber, characterized in that the joints of conductive conductors are installed in through cylindrical openings of a multi-seat insulator, made of high temperature insulating rubber, and the vulcanization temperature of oil and petrol resistant rubber can the cast-iron casing is lower than the melting temperature of the insulation of the conductors, the hose jacket of the cables to be connected and the soldered nodes of the conductive core connections. 2. The connector according to claim 1, characterized in that the multicore cables are output cables of the underwater device.