DE1110213B - Tuning device for television receivers - Google Patents

Description

Tuning device for television receivers The invention relates to a Tuning device for television receivers with a channel switch for those in the meter wave range lying receiving channels and a preferably continuously adjustable tuning device for the reception channels in the decimeter wave range.

In television receivers, it is customary to design the tuning device serving for the reception of channels in the bands I and 111 as a channel switch in which the RF pre-stage and the mixer, including the oscillator, are fixed and in which the parts used for tuning, e.g. B. the input band filter, the band filter arranged between the RF pre-stage and the mixer and the oscillator coil can be set by switching the coils to the desired channel. In such channel switches it is known to build the band filter arranged between the HF pre-stage and the mixer stage from a transformer whose secondary winding is connected in parallel to a fixed capacitive voltage divider with a grounded tap point. One capacitor of this voltage divider is often formed by the capacitance of the electron path between the control grid and the cathode of the mixing tube, the cathode of the mixing tube being grounded.

For connecting a tuning device that may have been built in at a later date for the receiving channels in the decimeter wave range to the channel switch it is known, the oscillator of the channel switch for the reception of the decimeter wave range switch off and in place of the transformers dimensioned for the individual channels use transformers matched to the intermediate frequency. In this case the mixer tube and the RF preamplifier act as an additional broadband amplifier for the intermediate frequency. The output voltage of the tuner for the decimeter wave range is fed to the antenna input in this case. However, this method is very disadvantageous because switching the channel switch to an additional reserve channel necessary is. For this it may be necessary to turn the channel switch over to the largest Set part of the receiving channels to band IV, so that a remote control is difficult to do.

It is also known to use the output terminals of the tuner for the decimeter wave range directly to the input of the mixer via a selector switch to connect. This voting device is another one with the voting organs Switch connected in such a way that with a vote in the decimeter wave range The HF preamp of the channel switch and the oscillator tube of the channel switch are switched off are, while with a vote in the meter wave range, the decimeter wave voting device is switched off. For this purpose z. B. the anode voltage for the tube in question switched off. However, this circuit has the disadvantage that the switchover is only possible in a very specific position of the tuning device can be made and that the circuit has a switch that is at a so-called hot spot so that relatively cumbersome operating means (Bowden cable, etc.) are required are.

It is also known to couple the output voltage of the DMW tuning device via a cable into the first intermediate frequency amplifier stage, in which a capacitive voltage divider is connected in parallel to the secondary coil of the band filter between the IF stage and mixer stage, the connection point a of which is grounded. With this circuit too, however, a switch must be provided for the Siänalweg, because otherwise the circles - for decimeter wave and meter wave reception would influence one another. This is due to the fact that in both cases it is the same frequency, namely the intermediate frequency.

The invention is based on the task of connecting the decimeter wave tuning device to the channel switch without opening the control grid of the mixer tube the desired signal must be switched ...

The invention consists in a tuning device for television receivers with a channel switch for the meter wave range. - receiving channels and with a preferably continuously adjustable tuning device for the receiving channels lying in the decimeter wave range, with the oscillator and mixer of the decimeter wave tuning device when receiving a transmitter lying in the meter wave range and the RF pre-tube (s) and the Oscillator tube of the meter shaft part by switching off an operating voltage, e.g. B. the anode voltage, and in which the mixer tube of the channel switch when receiving a transmitter lying in the decimeter wave range serves as an amplifier tube for the intermediate frequency output voltage of the tuning device, in the simultaneous application of the following features, some of which are known per se: a) the channel switch contains for each Receiving channel an inductance, z. B. the secondary side of a transformer in the input circuit of the mixer tube, to which a fixed capacitive voltage divider with a grounded tap point is connected in parallel; b) the connection point of the voltage divider with the end of the inductance facing away from the control grid of the mixing tube of the channel switch is supplied with the output voltage of the decimeter wave tuning device via a cable without the use of changeover switches; c) The capacity of the cable and possibly an additional capacity form the coupling capacity of a capacitively coupled band filter, via which the DMW tuning device is connected to the connection point, in such a way that disturbing fundamental and harmonics from the DMW tuning device or the channel switch do not pass through the Cable flow and can be broadcast by this.

Such an arrangement has the advantage that the channel switch in the Switching to the reception of a DMW transmitter does not need to be actuated. To switch it is only necessary to operate a switch that DC voltage leads. A distorting influence of the DMW tuner on the There is no transmission curve here, since the cable capacitance is used when dimensioning the capacitive voltage divider is also taken into account. Furthermore, in the invention Arrangement of disturbing fundamental waves and harmonics from the tuning devices not over transmitted by the cable and not broadcast by it.

An exemplary embodiment is provided to explain the invention in more detail described on the basis of the drawing.

1 shows a channel switch 1 with HF pre-stage 2, mixer 3 and oscillator 4 for receiving broadcasts in the meter-wave range (band I / III), in which the input signals are fed to the input circuit 5 of the HF pre-stage from an antenna 6 will. Although the RF pre-stage is implemented here in a cascode circuit, any other suitable type of circuit can also be used. The coupling from the anode of the last HF amplifier tube 7 to the control grid of the mixer tube 8 is carried out via a transformer 9 which, with the connected capacitors, forms a band filter of about 7 MHz bandwidth (with CCIR-Nonn). The windings of the transformer 9 as well as the voice coil of the oscillator 4 and possibly the input transformer have a different value for each receiving channel and are usually arranged on movable segments of the channel switch, which are brought into engagement with stationary contacts of the circuit depending on the desired receiving channel. A capacitive voltage divider 12 is connected in parallel with the secondary winding 11 of the transformer 9. The connection point of the capacitors 13 and 14 of this voltage divider 12 is connected to ground. The capacitor 14 can be formed by the input capacitance of the mixing tube (C "K). The output circuit 15 of the mixing tube forms part of the input band filter for the intermediate frequency amplifier, not shown. The circuit described so far is known.

In order to design such a circuit wholly or partially for the reception of broadcasts in the decimeter wave range, it has hitherto been customary to dimension the transformer 9 in such a way that it forms a band filter matched to the intermediate frequency with the connected capacitors. The output voltage of the additional device 16 used for tuning in the decimeter wave range was fed to the input circuit of the RF pre-stage. In another known circuit, the control grid of the mixing tube was switched from the transformer 9 to the output terminals of the additional device 16 by means of a switch (not shown).

In the circuit according to the invention, the output voltage of the additional device 16 is fed to the connection point 17 of the capacitor 13 with the end of the secondary winding 11 of the transformer 9 facing away from the control grid. The output capacitance 18 of the additional device 16 including the cable capacitance is parallel to the capacitor 13. It is therefore possible to include the output capacitance of the additional device in the size of the capacitor 13 so that the output capacitance has no distorting influence on the transmission curve. In the case of a subsequent installation of the additional device, the capacitance can be taken into account by connecting a capacitor 19 approximately the size of the output capacitance 18 in parallel to the capacitor 13 and removing it after the additional device has been connected. A switch 10 is used to switch from the RF pre-stage to the front-end device 16 or vice versa, which supplies the operating voltage in a manner known per se either to the channel switch (RF tube and oscillator) or to the front-end device. To reduce the influence of the output capacitance on the transmission curve, it can also be advantageous to build the capacitor 13 according to FIG. 2 from the series connection of two capacitors 13 a and 13 b and to connect the additional device to the connection point of these capacitors. It can be useful here to choose the capacitance values of the two capacitors 13 a and 13 b differently. In this circuit, too, a further capacitor 19 a can be connected in parallel to the capacitor 13 a to take account of the output capacitance. The capacitor 13 a can also be designed to be adjustable for the same purpose. The output terminals of the additional device 16 are connected to the channel switch via a cable 20. 3 shows a circuit in which the capacitance 21 of this cable forms the coupling capacitance of a capacitance-coupled band filter with inductances 22 and 23 connected in the series branches. This greatly reduces the influence of the cable capacitance. This capacity can be increased with a further capacity24. The inductance and the connected and transformed capacitances are dimensioned in such a way that the bandpass filter forms a damped resonance circuit which is tuned approximately to the middle of the IF passband. The band filter can be coupled critically or uncritically so that the intermediate frequency has a flattened broadband transmission curve such that the predetermined steepness of the Nyquist flank is the same for band 1 / III and band IV / V reception. The connection of the cable 20 in band filter design does not have to be made at the connection point of the capacitors 13c and 13d , but can of course also be made in accordance with FIG. 1 or 2. The inductances 22 and 23 are expediently arranged in a separate shielding can or in a shielding chamber of the additional device.

In FIG. 4, the inductances 22 and 23 of the band filter containing the cable 20 are designed as matching transformers. In this case, the transmission via such a cable can also be made free of direct voltage if transformers with separate windings at the beginning and end of the cable are used, if the transmission curve is deformed.

Claims (1)

PATENT CLAIMS: 1. Tuning device for television receivers with a channel switch for the receiving channels lying in the meter wave range and with a preferably continuously adjustable tuning device for the receiving channels lying in the decimeter wave range, with the oscillator and mixer of the decimeter wave tuning device when receiving a transmitter lying in the meter wave range and when receiving a decimeter wave tuning device lying transmitter the RF pre-tube (s) and the oscillator tube of the meter shaft part by switching off an operating voltage, z. For example, the anode voltage, are switched off and in which the mixing tube of the channel switch on receipt of a lying in the decimeter transmitter serves as an amplifier tube for the intermediate-frequency output voltage of the tuner characterized by simultaneous application of the following part, the g per se known features: a) the channel switch ( 1) contains an inductance (11) for each receiving channel, e.g. B. the secondary side of a transformer (9) in the input circuit of the mixing tube (8), which is connected in parallel with a fixed capacitive voltage divider (13, 14) with a grounded tap point (Fig. 1 to 3); b) the connection point (17) of the voltage divider (13, 14) with the end of the inductance (11) facing away from the control grid of the mixing tube (8) of the channel switch (1 ), the output voltage of the decimeter wave tuning device (16) via a cable (20) without Use of Umschaltem supplied (Fig. 1 to 4). c) The capacitance (21) of the cable (20) and possibly an additional capacitance (24) form the coupling capacitance of a capacitively coupled band filter via which the DMW tuning device (16) is connected to the connection point (17) in such a way that disruptive Fundamental waves and harmonics from the DMW tuning device (16) or the channel switch (1) cannot flow via the cable (20) and can be broadcast by this (Fig. 3). 2. Tuning device according to claim 1, characterized in that the band filter inductance (23) located at the beginning of the cable is arranged in a cut-off chamber of the DMW tuning device (16) and the band filter inductance (22) located at the cable end is arranged in a separate shielding container (Fig. 3) . 3. Tuning device according to spoke 1 and 2, characterized in that the band filter inductances (22, 23) are designed as matching transformers (Fig. 4). 4. Tuning device according to claim 1 to 3, characterized in that the capacitance of the capacitive voltage divider lying between the channel switch inductance (11) and ground from the parallel circuit of a capacitor (13) with the series connection of two capacitors (13 c, 13 d) is preferred of different capacities, at the connection point (17) of which the band filter is connected (Fig. 3). 5. Tuning device according to claim 4, characterized in that in the event of a subsequent installation of the DMW tuning device (16) of the capacitor (13 a) lying between ground and the connection point (17) is adjustable and / or that parallel to this capacitor Another capacitor (19 a) is connected, which is removed after the installation of the DMW tuning device (16) (Fig. 2 and 3). Publications considered: German Auslegeschrift T 6505 VIII a / 21 al (published on August 16, 1956); . USA. Patent No. 2,750,496; "Funkschau", 1958, issue 13, p. 323; "Radio-mentor", 1956, No. 5, pp. 298/299.