DE2327316A1 - TRANSMISSION SYSTEM FOR COOLED HIGH PERFORMANCE CABLES - Google Patents

Description

Applicant: Feiten & Guilleaume Kabelwerke Aktiengesellschaft 5 Cologne 80 ^:. Schanzen ^ road

Fl ¹ I-IOJ 5 Cologne-Mülheim, the l6. Time 1973

Ho / Zu ■ '· ■ "..--

Transmission system for cooled high-performance cables 1 -

The invention relates to a three-phase cable system from with a coolant, in particular water, cooled high-performance cables. ■ '". -

It is known that with a coolant., E.g. oil or water ^ cooled Cables, the coolant through the cable itself in one and in the opposite direction through a parallel to the cable to guide running pipe. It is off at the end of the cable where the coolant is pumped into the cable, a cooling station intended for cooling the coolant. The transfer of this principle to a three-phase system with three cable cores leads

409881/0453

Pl 4107 Ιό. May 197j?

to a three-phase cable system with three cable cores through which the coolant flows in the same direction and a common return pipe for the coolant and a common cooling station. With this structure, the return pipe can be used as a separate pipe
be designed or else, the three possibly conically insulated cable cores run in a known catfish in the return pipe
(DAS 1 067 099). However, it is used with the above cable systems
If a cable core or the return tube is injured, then it falls
the entire cable system.

The invention is based on the object of creating a transmission system of the type described at the outset, in which even if a cable core or the return pipe of the coolant fails
the transmission system while maintaining full transmission: - power can continue to be operated without interruption.

According to the invention, this is achieved in that the transmission system consists of four parallel cores of a single-core cable with an inner conductor through which the coolant flows
A cooling station is connected at the beginning and end and three wires are electrically loaded as well as the fourth wire as a reserve wire
serves. This makes it possible to act immediately in the event of a cable core failure
to switch to the reserve lead, so that the cable system without
Failure can continue to operate.

According to the invention, it is particularly advantageous if the coolant passes through two wires in one direction and through the other two
Veins flowing in the opposite direction. This division of the coolant circuit saves the separate return pipe that is present in known systems. The fourth, additional wire thus takes on the function of a coolant return pipe and also serves as an electrical reserve wire in the event of a fault. In addition, since the coolant circuit is

409881/0453

Fl 4107 1ϋ. M ai -19 73 --5 -

is divided that in normal operation two wires to conduct the Coolant in one and the other two for conducting in the serve in the opposite direction, it can be advantageous according to the invention if, in the event of a fault, i.e. if one wire fails, the coolant flows through two wires in one direction and flows through a vein in the opposite direction. This division of the cooling circuit allows it to be maintained the energy transfer in the cable system, however, the water throughput would decrease due to the failure of a coolant return and therefore the transmission power is lower when the cooling system continued to operate under the same operating conditions "vrürdo. According to the invention, the lowering of the transmission performance thereby largely avoided that in the two veins with coolant flowing in one direction, a temperature above the normal operating temperature of the undisturbed cable system and in the core with coolant flowing in the opposite direction, one above the operating pressure of the undisturbed The pressure in the cable system is present. Doing this for the long term The temperature rises that occur during the repair of the defective wire are entirely permissible, as this reduces the life expectancy of the wire is only insignificantly shortened.

Based on the embodiment shown in the accompanying drawings the invention is explained in more detail. Show it:

Pig. 1 a cable system according to the invention,

2 shows a cross section through a single-conductor cable of the cable system according to Fig. 1,

• Fig. 3 a diagram of individual characteristics, about the necessary, relative Pressure difference increase depending on the permitted temperature difference increase "at a certain related transmission power.

409881/0453

BAD ORJGiNAl.

Fl 4107 1β May. 1973 -Jp-

A erfindungsgeniäßes transmission system 1 (Fig. L), whose Transmission power can be 2000 MVA and more, consists of four individual, parallel wires 2 with the coolant 3, e.g. V / water, inner conductors 4 through which there is a flow (Fig. 2). Of these wires 2, three are electrically loaded, the fourth serves as a reserve wire. At the beginning and at the end of the wires 2 is each one connected for this common cooling station 5 in such a way that that the coolant 3 flows back through two wires 2 and back through the other two. The cooling stations 5 are Equipped in such a way that at any time, e.g. in the event of a fault, one of the four wires 2 and the return line can be disconnected immediately of the coolant only takes place via a wire 2. Furthermore, the four wires 2 are equipped with switches at their ends in such a way that that in the event of a wire failure, it can be released immediately and the power supply is taken over by the reserve wire will.

As can be seen from Fig. 2, there is each core 2 of the single-core cable from the inner conductor 4 through which the coolant 3 flows and in the interior of which a tube .6 enclosing a hollow channel serving for the coolant line is arranged. The inner conductor 4 consists e.g. of individual strands made of copper or aluminum. The tube 6 can be made of metal or plastic. To the inner conductor 4 a ladder slat 7 is arranged. This is followed by a ■ electrical insulation 8 made of plastic or oil-soaked paper, those of an electrical shield 9 * e.g. made of copper strips, is surrounded. The socle formed in this way is of a VJe Hr ohr 3 0, For example, made of aluminum, which has a layer 11 made of a plastic compound and a plastic jacket as external protection 12 owns.

The fourth, which is required, can be read from FIG. 3 are in order to connect the cable system to the cable system in the event of a fault in a core

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Pl iHCY l6. May 1973

to be able to continue to operate with full transmission capacity. Intended to
For example, the Tc temperature difference along the two is wrong. In the event of a malfunction, the coolant is guided in one direction. Increase cable cores by a maximum of hO <£ compared to the operating temperature in undisturbed operation, the pressure difference must be along the individual
Vein with opposite flow direction can be more than doubled. Tn the diagram mean:

S = transmission power in undisturbed operation

S - transmission power in disturbed operation

^ T = temperature increase in the veins with in one direction

flowing coolant in undisturbed operation
A T = temperature increase in the cores with coolant flowing in one direction during disrupted operation

^ p = pressure drop along the vein with opposite flow direction in the undisturbed bed life ^ - ■ ·

^ p = pressure drop along the vein with opposite flow direction in disturbed operation,

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Claims (4)

Pl 4107 Ιό. May L9 ^r ty - * - Patent claims: Three-phase cable system made up of high-performance cables cooled with a coolant, in particular water, characterized by four parallel cores of single-core cables (2) with the coolant (3) flowing through the inner tube ii (4) ,. which are connected to a cooling station (5) at their beginning and end .and three wires (2) are electrically loaded and the fourth serves as a reserve wire. 2. Three-phase current cable system according to claim 1, characterized in that the coolant (3) flows through two wires (2) in one direction and through the two other wires (2) in the opposite direction. 3. Three-phase cable system according to claim 1 or 2, characterized characterized that in the event of failure of a wire of the Single-core cable (2) the coolant (3) through two wires (2) in one and through one wire (2) in the opposite Direction flows. 4. Three-phase cable system according to claim 3, characterized in that in the veins (?.) Mifc in one direction flowing coolant (3) a temperature above the normal operating temperature of the undisturbed cable system (1) and in the vein (2) with in the coolant (3) flowing in the opposite direction, a pressure above the normal operating pressure of the undisturbed cable system (l) prevails, so that the transmission capacity of the undisturbed cable system (l) is maintained. 409881/045 3