DEN0008902MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: May 14, 1954. Advertised on April 26, 1956

GERMAN PATENT OFFICE

The invention relates to a frequency shift telegraph transmitter and aims at such a training of such a transmitter that this essentially only when it occurs a series of telegraphy steps to be transmitted is effective.

According to the invention is such a transmitter with at least one for this purpose. the Switching device which blocks transmitter stages, consisting of a grid-controlled switching tube, whose control grid circuit contains an i? C element with an input resistor and one parallel to it switched series circuit with a resistor and a holding capacitor, the 7? C element to generate a switching voltage, the telegraphy steps via a biased diode are fed.

Preferably in series with the input resistance in the control grid circuit of the interrupter a bias voltage source normally blocking the interrupter * and a grid current limiting resistor turned on.

With reference to the drawing, in which a transmitter according to the invention is shown partially in detail is, the invention is explained in more detail, for example. ,

In the drawing, a crystal-controlled oscillator is denoted by ι, its output voltage

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via a frequency multiplication stage 2. the catching grid of a pentode acting as a mixing tube 3 is fed. With the control grid of this pentode 3 is a relatively low one .5 frequency tuned high-frequency oscillator 4 coupled, the output frequency of which by means of a Control reactance 5 shifted according to the telegraphy steps fed to the input terminals 6 will.

The anode of the mixing tube 3 is coupled to the control grid circuit of a pentode amplifier 8 via a band filter 7. The amplified voltage is taken from a tuned anode circuit 9 of this tube and passed via a coupling capacitor 10 to the transmitter and amplifier stage 12 connected to an antenna 11. The transmitter described is normally blocked by suitable screen grid voltages of the pentodes 3 and 8. This is the case if there are no telegraphy steps to be transmitted, because then these screen grids are connected to earth via a switching contact a _t.

The telegraphy steps fed to the input terminals 7, in addition to the rule reactance 5, are also fed to a triode 14 via the line 13. The control grid of this triode is connected to the cathode via a grid resistor 15, so that the triode is normally conductive and The anode of a diode 17 is connected to the anode of the triode 14, the cathode of which is connected to earth via a resistor 18 and a voltage divider resistor 19. The cathode of the diode 17 is also connected to the Control grid of a triode 21 used as a switching tube. The cathode of the switching tube 21 is connected to the voltage divider resistor 19 via a cathode resistor 22. The resistors 22 and 19 together with a further resistor 23 form a voltage divider connected to the anode voltage line a high-speed relay A that d The aforementioned contact Ci ₁ in the screen grid circles of the transmitter tubes 3 and 8 is operated.

In the absence of the telegraphy steps to be transmitted at the input terminals 6, the triode 14 conducts current, and the anode of the diode 17 connected to the anode of this triode reaches a relatively low potential. The cathode potential of the diode 17 is due to the voltage occurring across the voltage divider resistor 19, which is selected to be so high, for. B. + 70 V that · when the triode 14 is energized, the diode 17 is blocked. Under these circumstances, the triode 21 is blocked by the voltage appearing at the cathode resistor 22. When the triode 21 is blocked, the relay A in the anode circuit is not energized and the normally open contact G ₁ is in the position shown.

As soon as 6 telegraphy steps of negative polarity are fed to the input terminals, the triode 14 is blocked in the rhythm of the steps to be transmitted, and the telegraphy steps occur more intensely and with positive polarity at the anode of the triode 14. The ones occurring at the anode positive steps have an amplitude that is considerably larger than the Sperryor stress the diode 17, whereby the telegraphy steps occur with positive polarity at the resistor 18. The resistor 18 forms the input resistance of the control grid circuit of the switching triode 21, which is released as soon as a telegraphic step occurs at resistor 18. Parallel to the input resistance 18 is the series connection of a series resistor 24 and a holding capacitor 25. When a telegraphic step occurs across the input resistor 18, the holding capacitor is 25 charged relatively quickly via the series resistor 24, which compared to the Input resistance 18 is small. In the space between two telegraphic steps to be transmitted the diode 17 is blocked again, and there is no voltage loss across the resistor 18 because of a current flowing through the resistor 16 and a diode 17. The one above the holding capacitor The voltage present then carries a discharge current over this capacitor Resistors 24 and 18 bring about, as a result of which, since the resistor 24 is small compared to the resistor 18 is, essentially the full voltage of the capacitor 25 across the resistor 18 occurs. This avoids that in the space between two successive steps a series of to transmitting telegraphy steps the switching triode 21 is blocked.

In this way, the switching triode 21 is continuously energized during the occurrence of a series of telegraphy steps to be transmitted, and the relay A remains energized. As a result, the normally open contact a _± remains actuated, as a result of which the screen grids of the transmitter tubes 3 and 8 are connected to the anode voltage line via a screen grid resistor 26 and the transmitter tubes 3 and 8 remain released. However, if a series of telegraphy steps has not been carried out for a long time, the original state of the circuit occurs again, but with a delay in order to prevent the transmitter from being switched off during a short pause in a series of telegraphy steps to be transmitted. This delay when switching off can be implemented in the illustrated circuit arrangement in a simple manner by a suitable choice of the discharge time constant of the holding capacitor 25.

In the circuit arrangement shown, suitable values for the most important parts are:

R 16 39,000 ohms

R 18 820 000 ohms

R 19 6 800 ohms

R 20 2.2 MOhm

R 22 330 ohms

R 23 22,000 ohms

R 24 27,000 Ohm C 25 0.1 HiF

The pick-up time of the high-speed switching relay A is about ι milliseconds.

The aforementioned quick switch-on and delayed switch-off are also achieved when at the circuit shown is part of the input

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Resistor 18 is used as a series resistor 24 will. -

With the values of the parts mentioned, the delay in switching off the transmitter is that brought about by the holding capacitor, about 200 milliseconds, which is sufficient, to prevent the transmitter from being switched off during the transmission of a telegraphic message.

Claims (4)

Patent claims: i. Transmitter for frequency shift telegraphy, characterized in that at least one one of the transmitter stages blocking switching device is provided, consisting of a grid-controlled interrupter (21), the control grid circuit contains an i? C element with an input resistance (18) and a series circuit made in parallel of a resistor (24) and a holding capacitor (25), the i? C element for generating a Switching voltage can be supplied to the telegraphy steps via a biased diode (17). 2. Transmitter according to claim 1, characterized in that in series with the input resistance (18) in the control grid circle of the interrupter (21) one the interrupter (21) normally blocking bias voltage source (voltage divider 23, 22, 19) and a grid current limiting resistor (20) is switched on. 3. Transmitter according to claim 2, characterized in that the input resistance (18) in the Control grid circuit of the interrupter (21) is at least ten times as large as the series resistance (24). ■ 4. Transmitter according to claim 3, characterized in that the grid current limiting resistor (20) in the control grid circuit of the interrupter (21) greater than the input resistance (18) is. 1 sheet of drawings