DE538528C - Changeable chain ladder with resistance compensation - Google Patents

Description

Variable chain ladder with resistance compensation When directed Receiving and sending wave energy with a fixed group of individual oscillators the interference method (maximum or minimum method) is used for compensation of the different times in which the incoming wave energy causes the individual .Schwinger hits, or to produce the phase difference when pivoting the directional beam Chain ladder. The energy of the individual transducers when receiving is not direct routed to the amplifier or telephone, but has to delay them Chain ladder happen, the length of which can be adjusted so that for the relevant Direction of arrival all receiver energies reach the telephone at the same time and then give maximum reception. The direction is derived from the length of the chain conductor of the incoming wave. In the case of directional transmission, the energy is given to the individual Transmitters fed via chain conductors of different lengths, depending on the desired phase difference and direction of the beam. ..

The basic circuit diagram of a "delay chain" is shown in Fig. 1. The receivers are shown at 50, 51, 52. The chain conductor consists of a number of suitably dimensioned alternating resistors 1, 2 ... 7 in series connection ut.l, also selected appropriately across the line switched alternating resistors 8, 9 ... 14. These alternating resistors, the size and type of which are irrelevant to the present invention, do not need to be the same as one another.The chain is closed at one end with a resistor 15 equal to its characteristic impedance, at the other end is for example a telephone 16. The individual chain links are led to contacts 17, 18 ... 24. Each receiver 50, 51 and 52, the energy of which is to be delayed by the chain shown, is connected with its one pole to the continuous line 25 and - placed with its other pole on a slip ring 30, 31 etc. Two brushes 4o, 6o ode connected to one another now run for each receiver r 41, 61 etc., one on the contact track 17 to 24, the other on the slip ring 30, 31 etc. belonging to the respective receiver.

The energy given to the chain by a receiver suffers at their wandering down the chain losses. These losses are not just due to them Watt losses of the chain elements themselves, but it also forms each other Receivers wandering on the chain have an even if only slight reflection and suction point. As a result of these losses, a recipient on the chain near the phone (contact 17) louder than at a distance from the telephone (contact 2 ¢). To this annoying phenomenon too eliminate, you switched between the contacts 17 to 24 and the chain. so-called balancing resistors 70, 71 ... 76. The size of these balancing resistors is determined experimentally or by calculation from the data of the chain, des Recipient and the number of recipients running on the chain at the same time.

The type of comparison described above now has certain disadvantages. If you want to avoid switching off the receiver when sliding from contact to contact, you have to make the brushes so wide that the two contacts are short-circuited at the transition from one contact to the other. For this moment, the balancing resistors lying on the two contacts, z. B. 70 and 71 or 74 and 75, connected in parallel, and the volume increases at this moment, depending on the conditions up to 4 times its normal amount. For a given chain and receiver resistance, the loudness difference is greater, the greater the balancing resistances are at the relevant point.

The subject of the present invention is now a circuit of the balancing resistors, which avoids this evil. The invention consists in the balancing resistors not as before between the chain contacts and the chain, but between the Chain contacts and the receiver are placed in series with this, in such a way, that in each case when switching a chain link corresponding to the switched off Part of the equalizing resistor is switched on. This ensures that the Jumps in the change in resistance when switching from contact to contact are considerable become smaller, because there is always only one short circuit of one corresponding to a chain link Resistance part takes place.

The technical design is relatively simple, if you split the slip rings 30, 31, etc. into parts, and expediently in as many parts as there are chain links, and between these parts the associated ones Chain links corresponding amounts of resistance. The sum of these is then equal to the chain resistance.

The basic structure of the invention is shown in FIG. There are now no resistances between the contacts 17, z8 ... 24 and the chain. For this purpose, the slip rings 30 ... are divided, so z. B. designed as collectors, and between the individual parts (KoIIektorlameIlen) 80 to 87 or 9o to 97, the balancing resistors i oö, ioi etc. or iio, iii etc. are placed. These resistors are dimensioned so that their sum is equal to the largest necessary balancing resistance 70 in the vicinity of the telephone of the circuit according to FIG. I. In the circuit of the invention, there are only jumps in volume if one of the resistors 100 to 116 is short-circuited during the transition of the slip ring brush from one part of the slip ring to the other. Since each of these resistances is only a fraction of the total adjustment, this jump in volume is so small that it is not perceived as annoying. It can be made as small as desired by choosing the subdivision of the former slip ring, so that more resistors are used than chain links, on the other hand, if the chain is finely subdivided, a common partial resistance can be used for several chain links so that the compensating resistance has fewer jumps. than the chain. In extreme cases, the slip ring itself can be designed as a continuously variable resistor (e.g. coil resistor).

The structure of the chains on which the idea of the invention is used finds is indifferent. It can be a pure choke chain or any trade combined chain. . ' The application of the invention is not to compensators limited, but can be used with advantage wherever variable chain ladders can be used under similar conditions. .

Claims (3)

PATENT CLAIMS: i. Variable chain ladder with resistance compensation, in particular for compensators for directional reception and transmission of wave energy, characterized in that the compensation resistance (ioo to io6, iio to i i6), which changes with the position of the chain contact, is in series with the oscillator (50, 51) between them and the chain sliding contact is placed. 2. Chain ladder according to claim i, characterized in that the equalizing resistor (ioo to i o6, i io to i 1 6) is divided into parts which are placed between contact pieces (collector lamellas) on which a sliding contact connected to (learn chain sliding contact) grinds . 3. Chain ladder according to claim t, characterized in that the compensating resistor is designed as a continuously variable resistor, its sliding contact is electrically connected to the chain sliding contact.