DE534562C - Method for determining electrically good conductive masses submerged in a liquid by determining the change in resistance of the liquid path between immersed current-carrying electrodes - Google Patents

Description

Method for determining good electrical conductivity in a liquid submerged water by determining the change in resistance of the liquid path, between immersed current carrying electrodes The invention relates to a method for the determination of electrically highly conductive, immersed in a liquid Masses by determining the change in resistance of the liquid path between immersed current-carrying electrodes. In particular for prospecting on Ships sunk on the seabed are known to use trailing electrodes on cables through the sea, so that the change in the resistance of the liquid path cynical the current-carrying electrodes the presence of a larger electric good conductive ground; that is, of a ship or the like, found in the liquid can be.

According to the invention, the electrodes are connected to a cable with a plurality of conductors connected in such a way that each conductor in two each with one electrode connected sections is divided; others. Ends synchronously rotating switches are arranged. So only half as many conductors are required in the cable as Electrodes are used.

Modifying the method according to the invention can be advantageous the electrodes are thus connected to a cable with a plurality of conductors be that half of the electrodes with one and the same conductor and the rest, between the former switched on, switched electrodes by separate conductors with the Measuring apparatus are connected.

The invention is shown in some exemplary embodiments in the drawing shown.

Fig.i shows. schematically the top view of one by two ships towed cable for the detection of sunken ships.

Fig. 2 shows schematically a vertical view.

Fig. 3 shows the formation of a cable in multiple conductors and rotary switches at its ends.

Fig.q. shows a further development of the cable with multiple conductors and: the connection of the electrodes.

Fig. 5 shows a vertical section: through a fairway channel with stationary electrodes.

Fig. 6 shows the top view of this.

In Fig. R and 2, the cable with multiple conductors is denoted by z, which is towed through the ships 2, 3: This cable is carried by a number of buoys 4, on which insulated conductors 5, 6 ;: 7, 8 :, 9, are provided: which are weighted down by the lead masses ii. The conductors 5 etc. are connected to the respective conductors of the cable i, and their other ends terminate in electrodes 12, 13 which are in contact with the sea water. The 'electrodes consist of tufts of bare wires made of steel or bronze about in length. The electrode wires are led at a certain distance from the sea floor. For example, electrodes are applied at about 20 m for a total sea depth of about 30 m.

Measuring devices provided on the two ships make it possible in each Time. The measurement of the resistance between two adjacent electrodes, for example 12, 13. If these electrodes go straight over a metal mass 14, then changes resistance between them, even when they are not in immediate Come into contact with the metal mass, and this change is immediately aboard the Ships established, so that the location of the metal wetness approximately and conveniently determined- can be.

According to Fig. 3, the cable contains four conductors, one of which, 15, is continuous, while the other j e are separated into two sections, -as 16, 17; 18, 19, 2o, 2i. Electrodes 26, 27; 28, 29; 30, 31 are correspondingly with connected to these conductor sections. The conductor 15 can also be used as a protective cable Metal reinforcement be formed. -There are switches on every ship, and each of the two has a conductive arm, which has conductive circle segments is rotating: on one of the ships, arm 22 is rotating via segments 36, 37, 38, 39, 4o. These segments are with .den ladder sections -16, 18, 2o of the cable connected by switching on the ammeter 23. The arm 22 is connected to the conductor i5 with the switching on of an alternating current source 24 of low frequency in connection. On the other ship is the arm 25 with three segments 32, 33, 34 in cooperation, which is connected to the other conductor sections 17, 19, 21 of the cable ladder connected '. The arms 22 and 25 are rotated synchronously.

In the position shown, z. B. a current through the electrode 28, the conductor section 18, the ammeter 23, the segment 37, the arm 22, the power source 24, the conductor 15, the arm 25, the segment 32, the conductor section 17 and the electrode 27. Man can thus determine the resistance between the two electrodes 27, 28: Since the switches both rotate in the direction of the arrows 35, it can be seen that the resistance between the electrodes 28, and 29, 29 and 30, 30 is measured one after the other and 3-1, 26 and 27, 27 and 28 -by observing the ammeter 23 can examine. The ammeters show a constant output in the absence of metal masses; if its deflection changes suddenly, it can be assumed with certainty that a sunk ship or some other metal mass is in the current field between the electrodes in question, which reduces the resistance.

In the embodiment shown in Figure 4, the cable contains a conductor 41, which runs the entire length of the cable and on which-half of all Elekfroden, namely the electrodes 42, 43, 44, 45, 46 are connected while the remaining electrodes 47, 48, 49, -50, each between the former, 51 are connected to the measuring apparatus by individual conductors. So it is enough a single switch on only one of the ships, to one behind the other the field of each group of neighboring electrodes. It does exist, however thereby a certain uncertainty in determining whether the metal mass z. B. between the electrodes 43 and -49 or between the electrodes 49 and 44 - located. This uncertainty can, however, be eliminated by removing the resistance of the Conductor, which connects the two electrodes, - measures. It goes without saying that other devices can also be used to monitor the electrical condition of the system, in particular it is possible to use the zero method for this purpose to be used for measuring the resistance of the circuits.

Fig. 5 and 6. show the application of the invention for the observation of a fairway channel, on the basis of which a number. of stationary electrodes 52, e.g. B. _durcKlemmplatten 53, and is held in a suitable position by floats 56. These electrodes are staggered, e.g. B. chessboard-like -in relation to each other, and are - connected by -individual conductors to an observation stand -54, in which -sich the measuring devices are. If a submarine 55 drives through the occupied ferry channel, then its travel through the. Changes in the electrical state of the circuits can be observed leading to the electrodes closest to the boat.

Claims (2)

PATENTAN'SPRÜ'C73E; i. Procedure for determining electrical good conductive masses immersed in a liquid by determining the change in resistance the liquid path between immersed current-carrying electrodes, thereby characterized in that the electrodes are connected to a cable having a plurality of conductors in such a way connected are that each conductor is divided into two sections each connected to an electrode is,. synchronously rotating switches are arranged at the ends. 2nd amendment of the method according to claim i, characterized in that the. Electrodes a cable with a plurality of conductors are connected so that the 'half the electrodes with one and the same conductor and the rest between the former electrodes that are switched on are connected to the measuring device by separate conductors.