NO138784B - HEAT EXCHANGER. - Google Patents

Description

Connection device for silent connection of a television receiver.

The present invention relates to a connection device for silent connection of a television receiver.

In modern television receivers where the high voltage to the final anode in the picture tube is provided by the line deflection coupling, the disadvantage occurs that the majority of the filaments in the receiver's discharge tube after the receiver is switched on already reach operating temperature before the filament in the output tube for the line deflection coupling and the saving diode are sufficiently heated to emit the necessary electrons. The energy saving diode in particular needs a very long heating time. As a result, full volume will be reproduced in the loudspeaker before the image is visible on the picture tube screen, as the saving diode must first reach operating temperature before a sufficiently high voltage is produced for the final anode in the picture tube.

In addition, they often become discharge tubes which

provides the negative regulation voltage for the automatic strength regulation provided by means of the return pulses which are also derived from the line deflection coupling. These return pulses are also only present with sufficient strength when the saving diode has reached operating temperature. This means that up to this moment no or almost no negative regulation voltage is produced. This can lead to an override of the last intermediate frequency amplifier tubes which already have an effective operating temperature, so that the received television signals are distorted and thereby also the already audible sound.

In order to avoid this disadvantage, according to the invention, it is proposed that the connection device comprises a discharge tube whose control grid and cathode, when the television receiver is connected via a capacitor respectively directly, is supplied with alternating voltage supplied from the mains, which discharge tube's anode is galvanically connected on one side to the control grid in at least one high-frequency amplifier tub pipe and/or with the guide grid in at least one

intermediate frequency amplifier tube, and on the other hand, across a resistor, a from is supplied

the receiver's line deflection coupling derives positive direct voltage as soon as the tubes in this deflection coupling have reached operating temperature, and that the discharge tube's control grid is connected via a further resistance to an outlet on the resistance across which the anode of the discharge tube is supplied with the positive direct voltage, so that high-frequency and/or intermediate frequency - the amplifier tubes are blocked by the negative direct voltage provided by the alternating voltage supplied to the discharge tube's control grid and are grid-rectified in this, until the tubes in the deflection coupling have reached operating temperature.

An embodiment of the invention will be explained in more detail with reference to the drawing showing a connection core for a device according to the invention.

In this embodiment, the discharge tube 1 has two functions.

Firstly, it fulfills the commonly known function as a threshold value tube for delaying the voltage for the automatic strength regulation, ensuring that the regulated high-frequency tubes only receive a negative regulation voltage when the strength of the incoming television signal exceeds a certain value.

Secondly, when the television receiver is switched on, the discharge tube 1 according to the invention itself supplies a negative voltage, by means of which the high-frequency and medium-frequency amplifier tubes which are galvanically connected to the anode in the discharge tube 1 are blocked until the tubes in the line deflection coupling have reached operating temperature.

Although the function of a threshold value tube and a blocking tube is combined in the design example, since in such a case an additional discharge tube is not necessary, it is obvious that these functions can also be separated and that an output can be used charging tube which is arranged in the figure in a similar way, without the regulation voltage for the automatic strength regulation being supplied to this circuit. In this case, this regulation voltage can be generated in a separate circuit and supplied to other than the medium-frequency and/or high-frequency tubes belonging to the blocking circuit which are to be regulated.

In the present embodiment, the two aforementioned functions are combined, as I said, and the threshold value tube 1 is for that purpose supplied via two equalization networks 2 and 3 to a discharge tube 4 which produces the regulation voltage for the automatic power regulation in the receiver. For that purpose, the cathode 5 in the discharge tube 4 is connected to the cathode 6 in the discharge tube 7, whose screen grid is supplied with the detected video signal. The cathodes 5 and 6 are connected to earth via the cathode resistor 8, and the anode in the tube 4 is supplied with the return pulses from the line deflection coupling via a capacitor 9, so that a negative regulation voltage is produced on the anode in the tube which is dependent on the strength of the detected video signal. The principle of the invention can be used for both negative signals and positive signals that are modulated on the image carrier wave. The present embodiment applies in particular to negatively modulated television signals, but it is obvious that in case of minor changes, e.g. since the tube 4 is not scanned at the occurrence of line synchronization pulses but at the occurrence of the leading and/or the trailing edge of these line pulses, can also be used for positively modulated television signals for generating a regulation voltage for automatic strength regulation with the connection device shown in the figure.

The negative regulation voltage that occurs on the anode in the tube 4 is supplied to the equalization network 3 which consists of the resistor 10 and the capacitor 11, equalized and supplied via the line 12 to one or more control grids in the intermediate frequency amplifier tubes to be regulated. This once equalized regulation voltage is again supplied to an equalization network 2 which consists of a resistor 13 and a capacitor 14 and the thus twice equalized regulation signal is supplied over the wire 15 to the control grid in one or more of the high-frequency amplifier tubes which are to regulated.

The anode in the threshold value tube 1 is connected to a positive DC voltage in a way that will be explained in more detail below. If a low-strength video signal is received, the voltage appearing on line 15 will still be somewhat positive to ground, as the negative regulation voltage appearing on the anode of tube 4 is too small to make the voltage on line 15 negative in relation to earth. The tube 1 then has a relatively high anode current, so that the voltage in the line 15 can only be very slightly positive in relation to ground. But a certain approximation can therefore be said that the grids in the high-frequency amplifier tubes to be regulated are approximately at ground potential. If this creates difficulties, then a small positive voltage can be supplied to the cathodes in these high-frequency tubes in such a way that even when the voltage on the line 15 is somewhat positive in relation to earth, the voltage difference between the control grid and the cathode in the high-frequency amplifier tubes to be regulated will be approximately 0 volts.

It was initially mentioned that shortly after switching on the receiver, the majority of its tubes are already at operating temperature, which is not the case with the line output tube 16 and the saving diode 17. Most tubes in the receiver have a heating time of 15-16 sec., while the line output tube 16 has a heating time of approx. 30 sec., and

the saving diode has a heating time of 50—

60 sec. This means that the high voltage which

provided by rectification of the flyback pulses that occur during operation in the transformer 18 by means of the diode 19, are not yet present as long as the saving diode is not sufficiently heated. Thus, no high voltage will occur on the anode 20 of the picture tube 21 before the moment in which the saving diode 17 has reached operating temperature, so that despite the fact that the discharge tube 7 supplies the complete video

signal, no image appears on the picture tube's 21 screen.

The channel not shown in the figure for amplifying and detecting the sound signal that is sent out with the television signal in question is, however, in full operation so that the thereby amplified and detected sound signals are audible in the loudspeaker before the image is displayed on the screen.

Moreover, no return pulses are supplied to the anode in the tube 4 via the capacitor 9 before the saving diode 17 has operating temperature. This means that no negative regulation voltage is produced, and the wires 12 and 15 have an approximate ground potential if special precautions are not taken. It follows from this that the high-frequency and medium-frequency amplifier tubes are set to maximum amplification, so that there is a danger that when strong television signals are received, the last intermediate-frequency tubes will be overridden. In the case of modern television receivers that work according to the difference carrier principle, the sound signals will consequently be distorted so that the audible sound signals are also distorted, which is undesirable.

In order to eliminate this disadvantage, according to the invention, the threshold value tube 1 is also used to ensure, after switching on the receiver, that the regulated high-frequency and medium-frequency amplifier tubes are blocked until the saving diode has reached operating temperature.

For that purpose, primarily the positive direct voltage for the threshold value tube 1 across the resistors 22 and 23 is taken from the capacitor 24 which belongs to the saving diode circuit. As is known, the voltage at the connection point between the capacitor 24 and one end of the primary winding in the line output transformer 18 will be approx. 800-900 volts. However, this high positive direct voltage is only produced when both the line output tube 16 and the saving diode 17 have reached operating temperature. Before this voltage appears, the threshold value tube 1 will already be conducting current for a long time, and for this tube a type is chosen such that the heating time of the filament is even shorter than that of the medium-frequency and high-frequency amplifier tubes. The heating time for the filament in tube 1 can e.g. be approx. 6 sec. after the receiver's connection.

Alternatively, the cathode 29 and the control grid 25 in the tube 1 become indirect, e.g. over a capacitor 26, connected to a preferably approximately sinusoidal alternating voltage, e.g. mains voltage or part of it. For this purpose, the capacitor 26 is connected to a point on the mains voltage switch

27 so that upon the receiver's connection at

closing the switch 27, an alternating voltage is taken from the mains which acts on the grid and the cathode in the tube 1. When the tube 1 carries a current after heating, the capacitor 26 is charged up by means of the current flowing to the control grid 25, in such a way that the pole of the capacitor 26 connected to the control grid 25 becomes negative in relation to ground.

The control grid 25 is further connected via the resistance 28 to the connection point between the resistances 22 and 23. As long as the saving diode 17 has not reached operating temperature, no positive direct voltage will be produced, so that the tube 4 does not produce a negative regulation voltage. All points in the connection can thus be regarded as floating, and the capacitors 14 and 11 are also charged in such a way that the coatings of these capacitors, which are connected to the lines 15 and 12, assume the same negative voltage in relation to earth as the aforementioned pole in the capacitor 26. This negative voltage is chosen so that the high-frequency and medium-frequency amplifier tubes to be regulated are blocked. The opposite television signal is thus not passed on, and no distorted sound can be heard in the speaker.

If the operating temperature of the saving diode 17 is then increased, a positive direct voltage of 800-900 volts occurs at the end of the resistor 23 which faces the resistor 28.

negative charge on the pole of the capacitor 26 which is connected to the control grid 25 can thus be led away, and the control grid 25 becomes somewhat positive in relation to earth. Then it

negative voltage on the capacitors 14 and 11 as a result also disappears, and the return pulse across the capacitor 9 is supplied to the anode in the tube 4, the necessary negative regulation voltage can be produced, and all individual parts in the receiver are brought to a normal state, so that simultaneously with that the image appears on the picture screen, the sound also appears undistorted in the speaker.

In order for this mentioned condition to be maintained under normal operating conditions, the current that flows through the resistors 23 and 28 must be greater than the charging current that can flow through the capacitor

26 in approximately a quarter of the previous period

occurrence of the positive mains voltage peak (the current through the capacitor 26 has a head start on the voltage which

occurs across the capacitor at almost 90°, as the impedance between grid and cathode in the discharge ear at the floating grid current is so small that one can disregard

den), as there is otherwise a danger that a small negative charge can nevertheless be produced on the coating of the capacitor 26 which is connected to the control grid 25. This can be avoided by setting a value of 800-900 volts for the positive direct voltage that is taken from the capacitor 24 selects the total resistance value of the resistors 23 and 28 so that the current that flows through these resistors exceeds the mentioned possible charging current of the capacitor 26. This means that the grid current that flows to the control grid 25 flows entirely through the resistors 23 and 28 and never through the capacitor 26.

It should be noted that the positive direct voltage which is supplied to the anode in the threshold value tube 1 across resistors 22 and 23 can also be achieved in such a way that the flyback pulses appearing in the transformer 18 can be rectified separately. Also in this case, this positive voltage will only be present when both the line output tube 16 and the saving diode 17 have reached operating temperature.

The regulation voltage, which in this example is produced by means of the controlled discharge tube 4, can also be achieved in another way, e.g. by simple rectification of the incoming television signals using a diode. In this case, one does not have the disadvantage of overriding the last intermediate frequency amplifier tubes, but the disadvantage that sound occurs in the loudspeaker before the image is displayed on the screen, and this can be remedied in the above-mentioned manner. It is immaterial to the operation of the switching device in which way the negative regulation voltage is produced.

Also in receivers where the difference-carrier principle is not used, the disadvantage is that the sound is audible before the image is visible. In this case too, the precautionary rule according to the invention can be applied, and it must be ensured that the blocking of the regulated high-frequency tubes is such that the sound carrier wave modulated in a low-frequency rhythm is not transferred to the channel which is tuned to the intermediate audio frequency.

It should be noted that the capacitor 26 must not have too small an impedance for alternating current of 50 Hz, as otherwise the direct current for the control grid 25 assumes an inadmissible value. In the present example, the capacity value of the capacitor 26 is therefore chosen equal to 2000 pF.

Claims (3)

1. Connection device for silent connection of a television receiver, characterized in that it comprises a discharge tube (1) whose control grid (25) and cathode (29) at the connection of the television receiver, over a capacitor (26), or directly supplied from the mains supply alternating voltage, which discharge tube's anode is on the one hand galvanically connected to the control grid of at least one high-frequency amplifier tube and/or to the control grid of at least one medium-frequency amplifier tube, and on the other hand via a resistor (22, 23) is supplied from the receiver's line deflection coupling derived positive direct voltage as soon as the tubes in this deflection coupling have reached operating temperature, and that the discharge tube's control grid (25) via a further resistance (28) is connected to an outlet on the resistance (22, 23) via which the anode of the discharge tube is supplied with the positive direct voltage, as that the high-frequency and/or medium-frequency amplifier tubes are blocked by the negative DC voltage provided by the alternating voltage which is supplied to the discharge tube's control grid and is grid rectified in this, until the tubes in the deflection coupling have reached operating temperature. 2. Coupling device according to claim 1, characterized in that the threshold value tube for the circuit which generates the control voltage for the automatic gain control is used as the discharge tube. 3. Coupling device according to claim 1 or 2, characterized in that the part (23) of the resistance over which the positive direct voltage is supplied to the anode of the discharge tube, and which lies between the said outlet and the deflection coupling, and the further resistance (28) between this outlet and the control grid (25) of the discharge tube (1), has such a total resistance value that the current through these resistors at the aforementioned supplied positive direct voltage exceeds the charging current through these resistors to the capacitor connected to the control grid, which current can flow in approximately one quarter of the aforementioned alternating voltage period before the appearance of the positive mains voltage peak of the connected mains voltage.