RU66106U1 - HEAT-RESISTANT CABLE - Google Patents

Abstract

The technical solution relates to cable products, and can be used in devices for transmitting signals installed mainly at technical facilities operating in extreme conditions. The claimed technical solution is possible for the manufacture of cables of small diameters, designed: for transmitting weak signals, control signals, as well as in power cables. The task of reducing the outer diameter of two, or three, or four-core cable in diameter is solved as follows. Heat-resistant cable having from 2 to 4 conductive cores placed in the outer metal sheath, where the cores are isolated from the sheath and between each other with a mineral filler. The cross section of the conductive conductors has the form of sectors or segments that fill the space in the shell as much as possible, the layer of mineral filler provides, at the same time, sufficient insulation between the conductive conductors and the outer metal shell. If necessary, current-carrying conductors in the cable can be twisted.

Description

The claimed technical solution relates to cable products, and can be used in devices for transmitting signals installed mainly at objects of equipment operating in extreme conditions including nuclear energy. The claimed technical solution can be used for the manufacture of cables with small-diameter conductors, designed: for transmitting weak signals, control signals, as well as in power cables.

Known cable containing a sealed metal sheath, in which are placed current-carrying conductors, isolated from each other and the shell with magnesia insulation (see V.F. Suchkov, V.I. Svetlova, E.E. Finkel. "Heat-resistant cables with magnesia insulation" , M., Energy, 1969, p. 3, 4). This cable has high performance even in aggressive environments and at high temperatures.

However, this cable has several significant drawbacks. With a decrease in the overall dimensions of the cable, and a decrease in the cross section of current-carrying conductors, resistance increases and conductivity decreases, which is an important factor for long lines along which weak signals are transmitted.

Closest to the claimed is the cable described in the application WO0029117. The cable is a metal sheath in which conductors are placed, insulated from each other and sheaths with mineral insulation. The cross section of the conductors is round.

The disadvantages of this cable are: the inability to manufacture a thin cable with a diameter of up to 1 mm or less, with low electrical resistance of current-carrying conductors. The claimed technical solution is aimed at creating cables with mineral insulation, having the same overall dimensions with analogues, but at the same time, lower, compared with them, electrical resistance of conductive conductors; or cables having, with the same electrical resistance, smaller outer diameters.

The technical result from the use of the proposed solution is that it becomes possible to increase the cross-section of the current-carrying conductors of the cable, in comparison with well-known analogues having round current-carrying conductors, from 1.4 to 2.4 times. An increase in the cross section is possible due to a change in the shape of the cross section of the conductive wires. The inventive cores are in the form of segments, or sectors, as much as possible filling the space inside the shell, while between the conductive cores and the shell provides sufficient insulation.

If necessary, current-carrying conductors can be twisted.

A cable is declared consisting of an external sealed metal sheath that is filled with insulating mineral material that insulates

conductive conductors between themselves and from the outer shell. Veins having a section in the form of sectors or segments fill the space in the shell to the maximum, while the insulating mineral filler provides sufficient insulation.

Depending on the purpose of the cable, it is possible to make a sheath of various metals and alloys. In this case, it is possible to manufacture a cable with conductors in the form of sectors, or segments for transmitting weak signals, control signals, as well as for power lines.

Cables are advisable to produce two-, three- or four-core.

The current load on the cores can be increased, respectively, with the same overall characteristics of the cables. An increase in the current load on the cable is not a critical factor for him in terms of heating temperature since mineral insulation, for example MgO, melts at a temperature of about 2800 degrees. C, and the heating of conductive conductors can reach 800 degrees. S. and more.

For the transmission of weak signals in the circuits of measuring equipment, with a minimum outer diameter of the cable, the option of using a cable with segmented conductors has undeniable advantages, compared with the option of using a cable with traditional round conductors.

A cable with segmented conductors has a low electrical resistance of more than 2 times as compared with a cable of the same diameter having round conductors.

Figure 1 shows a two-core cable, where 1 is a sheath, 2 is mineral insulation, 3 is conductive conductors; figure 2 presents a three-core cable, where 1 is a sheath, 2 is mineral insulation, 3 is conductive conductors; figure 3 presents a four-core cable, where 1 is a sheath, 2 is mineral insulation, 3 is conductive conductors.

Cable examples:

1. A twin-core cable having an outer diameter of 1 mm. The shell is made of Inconel 600 alloy. Mineral insulation is made of Al ₂ O ₃ . Conductors are made of Inconel 600 alloy. The electrical resistance of the conductors is reduced by 2.4 times.

2. A three-core cable having an outer diameter of 1.5 mm. The shell is made of alloy 321. The filler is made of MgO. Conductors made of copper. The electrical resistance of the cores is reduced by 1.7 times. Cable diameters from 1.5 mm and above.

3. A four-core cable having an outer diameter of 2 mm. The shell is made of alloy 321, the filler is made of MgO. Conductors are made of oxygen-free copper. The electrical resistance of the cores is reduced by 1.4 times. Diameter of cables from 2 mm and above.

Claims (2)

1. Heat-resistant cable made in the form of an outer metal sheath, in which from two to four conductive cores are insulated from each other and insulated with mineral insulation, characterized in that the cross-section of conductive conductors has the form of sectors or segments that fill the space in the enclosure as much as possible while the layer of mineral insulation between the conductive conductors and the outer metal sheath provides sufficient insulation. 2. The heat-resistant cable according to claim 1, characterized in that the conductive wires are twisted.