DE460642C - Cable with artificial cooling - Google Patents

Description

It is known that when current is carried through a TCable in the conductors the metal resistance of the conductor develops heat. This heat must be dissipated because with greater heating the impregnation compound is pressed out of the cable and with further heating it is pushed in Charging of the dielectric occurs, which can lead to breakdown of the cable.

Up until now, the heat has been dissipated naturally through its release to the substances surrounding the cable (e.g. earth, air, water, etc.). So that no overheating of the cable occurs the cross-sections of the cable set according to the load, so that at a given Load a certain cross-section is used, whereby for its determination (besides the stress) also the effect of the natural cooling is taken into account, which is caused by the environment of the cable is conditional.

The invention relates to a device through which on an artificial path the lead cable, the heat is withdrawn, so that the cables manufactured according to the invention can be loaded with electricity significantly higher than normal cables, or that for Line of a certain amperage, significantly smaller cross-sections can be used can be compared to cables without this facility.

For example, cables for low voltages would do a lot can absorb higher currents than normal cables of the same cross-section.

With the same current strength, the copper cross-section of the cable according to the invention, especially at low voltages, a fraction of the cross-section of a normal cable be.

The artificial cooling of the cable can take place according to the invention by 'that in cavities (channels) are provided in the lead jacket, which serve to dissipate the heat. This dissipation of heat takes place by cooling by means of circulation or passageways, e.g. B. from water, air, etc.

Several examples of cables according to the invention are shown in the drawing. Fig. Ι shows z. B. a three-core cable. It denotes 1, 2, 3 the metal conductor, 4 the dielectric, 5 the lead jacket, α cavities in the lead jacket, the number of which can be selected according to the respective conditions.

Another embodiment is shown in Fig. 2

also on a three-core cable. Here the cavities are achieved by providing the cable with two lead sheaths and inserting inserts (e.g. made of metal) between the two lead sheaths in such a way that hollow spaces are created. These cavities are now used in the manner indicated above for the artificial dissipation of heat. In Fig. 2 ίο i, 2, 3 denote the metal conductors, 4 the dielectric, 5 the inner lead jacket, 6 the outer lead jacket, α the cavities, b the inserts, the number of which can also be selected according to the respective conditions. Instead of using inlays, the construction can also be made so that the inner lead jacket contains outer ribs or the outer lead jacket contains inner ribs (see Figs. 3A and 3B), in which 1, 2, 3 the metal conductors, 4 the dielectric, 5 the inner lead, 6 the outer lead jacket, b the ribs attached to the lead jacket and a the cavities.

These latter embodiments according to Fig. 2, 3A and 3B have the special Advantage that if the outer lead jacket is damaged, the cable will also continue to do so remains operational. Furthermore, with these latter types of execution of the Ka- ■ bels still has the advantage that it can be used in conjunction with a simple reporting device, which is triggered by pressure differences, can easily achieve that damage of the outer lead jacket is indicated by this reporting device, so that the Repair of the outer lead jacket can be made before there is a breakdown would occur.

To report damage to the cable sheath caused by the damage in the ducts In order to achieve a pressure difference, it is most expedient to turn the ducts into two groups form in such a way that, if one considers the channels, from a certain channel catch e.g. B. clockwise, numbered, all even-numbered channels in the one Group, e.g. II, and all odd-numbered channels in another group, namely in Group I, summarized, d. H. can be made to communicate with each other. This combination of one group is in one or more arbitrary places of the cable, preferably at the point where the signaling device is to be connected by means of the pressure difference that may occur is to be brought into action.

Wherever dangerous damage to the lead jacket occurs, there will be a pressure difference between the channels of group I and those of group II form, regardless of whether the coolant is on tapped at any point on the cable or not. Because when tapping the Coolant has both group I and group II, which may be used at the tapping point should also be connected, a very specific volume resistance to overcome. If this volume resistance is reduced by the fact that at any point on the cable, be it in the Group I or in group II, for the tap opening If another opening is added, the volume resistance is reduced one group, e.g. B. I, while the other, e.g. B. II, remains as it is at The cable was intact. As a result, this changes earlier in the reporting device Receipt of the two prints set as idle state, and the reporting device comes into action. Any change in the volume resistance, which occurs when the mentioned Coolant could result, changes nothing in this ratio, because the two channels at the tapping points Group I and Group II are communicating; this change in volume resistance thus acts equally on both I and II, so that the correct effect of the Reporting device is not affected. Artificial cooling can be performed according to the respective load can be increased or decreased that the cooling circulation is accelerated or slowed down or that fewer or more cavities for drainage the heat can be used.

With the artificial heat dissipation there is also an economic advantage, by drawing off the coolant (water, air) that has become warm as a result of the current load from the cable line from point to point and can be made usable in baths, laundry facilities, etc.

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Claims (4)

Patent to sprttche: 1. Cable with artificial cooling, characterized in that in the lead sheath of the cable channels are provided, which for the reception or forwarding of cool ! end means, e.g. B. water or air, serve. 2. Cable with artificial cooling according to claim 1, characterized in that the channels serving for receiving or forwarding coolants are formed by two lead jackets and inserts or ribs built between them. 3. Cable with artificial cooling according to claim 1, characterized in that this is due to the current load on the cable heated coolant to utilize the heat contained in the agent Cable is tapped. 4. Cable with artificial cooling according to claim 1 to 3, characterized in that that the channels used for cooling are connected in such a way that pressure differences arise if the lead jacket is damaged result in the coolant between the individual channels. For this purpose ι sheet of drawings.