DE300001C - - Google Patents

Description

In the case of wireless telegraphy with detector reception, very weak pulsating Direct currents that can initially only be used for audio reception. The present Invention now relates to a receiving arrangement by means of which it is possible to weak to make pulsating direct or alternating currents useful for relay operation; through this it is achieved that when the detector is received in

ίο the cables through wireless telegraphy Morse code written down, "or that by wireless signaling mechanical devices, such as remote control devices, can be put into operation.

The arrangement described in more detail below achieves its purpose in that the very weak detector currents through suitable devices to a certain extent Degree are amplified, and that the amplified direct or alternating currents are then used for relay reception be made useful.

In Fig. Ι shows ι the antenna, 2 a variable capacitor, 3 a self-induction, 4 the self-induction of the secondary circuit, to which the detector 5 and a capacitor 6 is connected. In parallel to the capacitor layer 6, lead wires now run out, to which a telephone is usually attached to listen to the dispatches. In the above arrangement, these lead wires • go to a transformer 7, 8, which converts the pulsating DC currents into AC currents. I, II, III, IV are cathode ray lamps which amplify the pulsating weak currents in a known manner. 9 shows the grid, 10 the filament, 11 the anode of the lamp, 12 is a resistor, 13 is a 6 volt battery, 14 is a high voltage battery of about 100 volts. By cascading several such lamps, the pulsating direct currents of the detector are now amplified very significantly.

There are now two makes of cathode amplifiers. One becomes a amplified pulsating direct current taken directly from terminals 17, 18 or 24, 23, while with the other make a transformer 19, 20 is provided, which at the end at the terminals 21, 22 emits an increased alternating current.

Fig. Ι shows these two embodiments combined. V illustrates the combined relay apparatus, which is shown in detail in Fig. 2, with its starting terminals a, b and i, h and its end terminals r, see Wave impulses converted into current impulses are written down as telegraphic characters on a strip of paper.

If the terminals 24, 23 are connected to a, b , the anode current is used for relay operation; the transformer 19, 20 with the

Terminals 21, 22 are to be regarded as not available. If the transformer 19, 20 is present in the other embodiment, then the terminals 21, 22 are connected to the terminals i, h in FIG. 2. The line that started from 23, 24 and led to a, b is here to be regarded as non-existent.

Fig. 2 now shows an arrangement by means of

which it is possible to use a relay as soon as possible to the cathode lamp amplifiers of the first kind as well as to those of the second kind to use.

e, f forms a transformer, of which the high-resistance winding e can also be used as a choke coil, k is a crystal detector which acts as a thermocouple and converts alternating currents into pulsating direct currents, η is a capacitor, 0 a highly sensitive galvanometer, p a polarized relay , q a capacitor placed parallel to the winding of the relay p , ab, ih, rs are current connection terminals or openings for piercing contacts. From c, g. M, y leads from lines that can be applied through connection plugs to both the horizontally lying contact d, h, I and x, as well as to the vertically drawn connection openings u, ζ, t, w ¹ , w ² , w ³ .

If these connection plugs are connected horizontally, the device is suitable for relay operation with incoming alternating currents. If the connection plugs are connected vertically, the arrangement is suitable for using pulsating direct currents for relay operation. In this case, the incoming direct current goes from connection point a to connection point t, to plug m, through galvanometer 0, through polarized relay p to plug y, from connection point χ and u via plug c to b.

Since the high-voltage battery 14 (Fig. 1) still emits a weak direct current when no characters arrive, this anode direct current would bring the GaI vanometer 0 to .Ausschlag and the relay p into contact position. However, this should only be the case if the anode current is increased by incoming characters. It is therefore possible to receive the relay through the incoming characters in that the polarized relay is weakened by approaching opposing magnetic poles until the tongue is out of contact and only makes contact due to the increased anode currents during the signaling. Secondly, the relay can be contacted for incoming characters in that a direct current of the same strength canceling the anode current is passed in the opposite direction through the winding of the relay p . The current path ■ of this compensation direct current is as follows: + -terminal of the battery w, connection plug w ¹ , w * or w ³ , plug y, relay p, galvanometer 0, plug m, connection point t, choke coil e, connection point d, choke coil v, + -Pole of the battery w.

The mode of action is now as follows:
Case i. A lamp amplifier is used in which at the end the anode current is taken directly from the terminals 23, 24, the transformer ig, 20 is not in front. All plugs are switched vertically, but the plug y is left in connection with the connection opening χ. The anode direct current now goes in the manner described above from the connection terminal α through t, m, 0, p, y, x, u, c, b and brings the relay tongue into contact position. Becomes by approaching a

] Regulating magnets compensate for the magnetism of the direct current in the relay, the tongue falls back into the rest position and only comes into contact position through the increased pulsating direct current with incoming characters, so that the incoming characters at the terminals r, s by connecting a Morse code in series and a battery can be written down. Case 2. A lamp amplifier is used as in case 1. All connection plugs are switched vertically. The anode. direct current, which can be seen from the deflection of the galvanometer 0 , is compensated by the countercurrent of the battery w , whereby the plug y can be placed in the connection opening w ¹ or w ² or w ³ until the galvanometer deflection goes back to the zero position and indicates that full compensation is achieved. If too much voltage of the compensation current of the battery w joo

I used, the galvanometer deflects on the opposite side. One takes as a result, a little less voltage and by regulating the ohmic resistance

I stand at the choke coil ν complete

i Compensation and zeroing of the galvanometer obtained.

The incoming radiotelegraphic

I characters cause a pulsating amplification of the anode direct current, which now mainly goes from α to t, m, 0, p, x, u, c, b and brings the galvanometer to deflection and the relay into contact position. The path from α through e, d, v, w, y, x, u, c, b is dem

j pulsating anode direct current is almost completely blocked, because firstly the current of the battery w has the opposite potential, secondly the choke coils e and ν oppose a very high resistance to the pulsating currents. Between y and χ is through lead wires

connection also available when the plug. el c to the connection opening u and the

. Plug y has been brought to one of the connection openings w ¹ or w ^% or w ^{3 of} the battery w . The connection plug g , however, has no wire connection with h when it is brought into the switch-off opening ζ . Likewise, the connector plug c is disconnected from d when it is connected to u . The connection plug m is also not connected to I when it is in the | opening t is inserted.

Case 3. A stronger lamp is used as in cases 1 and 2. All cable plugs are connected horizontally, i.e. c with d, m with I, g with h and y with x. The anode current goes from the terminal α through the winding e of the transformer e, f and via d, c, b back to the lamp amplifier. The evenly flowing anodem current, which is present as long as no characters arrive, has no effect on the transformer winding f. Soba'd but radiote'e-. When graphical characters arrive, an intensified pulsating anode direct current is generated, which generates secondary alternating current in the winding f of the transformer e, f. This comes from the coil f on the Auschlußöffnung i, k by the detector to the connection opening I, m to the stopper, n via the capacitor, h for connection opening, g to the stopper and f back to the winding. In the detector, k is formed by the alternating current a Heating of the contact points and consequently a thermoelectric direct current, which can be used to excite the relay ft and takes the following path: k, I, m, 0, ft, h, g, f, ^ back to k. The capacitor η blocked the thermal DC the short distance between h and m, but lets the alternating current through it. however, it is used in conjunction with the capacitor Q to the accumulation of the direct current, which then over the relay winding ft discharges and gets a significantly favorable effect.

Case 4, a lamp amplifier is used, in which there is a transformer at the end, so that alternating current. at the terminals 21, 22 can be removed, which is only present when radio telegraphic characters arrive. Since a transformer 19, 20 (Fig. 1) is already attached to the end of the amplifier, the transformer e, f (Fig. 2) is superfluous and can be connected by connecting the terminals 21, 22 (Fig. 1) with *, h (Fig. 2) and can be switched off by * connecting the plug g to the rest position ζ . All other connections remain as in case 3. The mode of operation is also identical to the above case.

A plurality of detectors connected in parallel or in series can also be used in place of detector k. Instead of the detectors, other thermocouples or rectifier cells can also be used.

Claims (6)

Patent Claims: 1. Electrical device to use weakly pulsating ^{;, J} direct or alternating currents for relay operation, characterized in that the weak electrical currents are first amplified by cathode lamp amplifiers and the powerfully pulsating anode currents aldann either after being converted into alternating currents by means of a transformer back into relay operation suitable direct currents are converted or, omitting the transformer and switching on a current source that is interconnected with control resistors or choke coils and compensates for the normally flowing anode current, are mainly routed via the relay. 2. Electrical device according to claim i, characterized in that the alternating currents generated from the powerfully pulsating anode currents by a transformer through thermocouples or Rectifiers can be converted back into direct currents, through which a relay is operated. 3. Electrical device according to claims ι and 2, characterized in that the pulsating direct currents are passed directly through a relay (ft) through , 'which at the same time a direct current is conducted in the opposite direction, which emanates from a current source of low voltage and is regulated by resistors (e, v), which form choke coils for pulsating currents, so that the normally flowing anode current is compensated, while the at Excitation strong, pulsating anode direct current mainly goes through the relay {ft) and makes it respond. 4. Electrical device according to claims ι to 3, characterized in that that to convert the alternating current into direct current a detector (A) in arrangements is used, as it is otherwise used in wireless telegraphy, with parallel or series connection multiple detectors to increase the effect advantageously used can be. 5. Electrical device according to claims ι to 4, characterized in that parallel to the winding of the relay (ft) a large capacitor (q) attached j by switching the current paths both which increases the effect. j as resistance for the compensation 6. Electrical device according to the on ' : direct current, as well as a choke coil for Proverbs ι to 5, characterized in that i uses the pulsating anode current that the winding of a transformer can become (e, f) \ . 1 sheet of drawings. REKMN. GIILUCT IN THE THROAT PRESSURE.