DE1032424B - Circuit arrangement for protecting the screen of a cathode ray tube against overload - Google Patents

Description

GERMAN

With cathode ray tubes, preferably with picture recording and display tubes for television purposes, Considerable damage to the glider can occur if one or both deflections fail (en) the electron beam only describes a simple line instead of a complete grid or even stands still.

With cathode ray tubes, their anode high voltage from the return pulses of the line deflection circuit is obtained, screen damage is less to be feared because of disturbances in the line deflection circle the high voltage generation is also interrupted. In such a circuit you can Damage only occurs with disturbances in the image deflection (raster deflection) alone, but this is relative is rare.

However, the above-mentioned dangers of damage to the shield exist in particular if for the A special generator is used to generate high voltage, which is independent of the deflection circuits is. This is preferably the case with devices that require a relatively high beam power, z. B. in projection televisions.

With projection arrangements in particular, the picture tube is already set when the surface grid is fully written out very heavily loaded, and overloading and damage to the shield are not only to be expected if the Electron beam at one and the same point for a long time as a result of the failure of both deflection devices directed, but also when, as a result of the failure, only the vertical or the horizontal Deflection device alone the electron beam writes a (horizontal or vertical) line. So it is It is necessary that the electron beam is complete even if any of the deflection devices is disturbed is suppressed.

In order to avoid these disadvantages mentioned, one has already passed one or both deflection circles Rectification of voltages taken and for blocking or opening one or more discharge tubes used, through which the voltage of an intensity control electrode of the cathode ray tube in the event of interference was changed in such a way that the radiation intensity was considerably reduced. For example one has through Rectification of the kickback pulses creates a negative voltage and the grid of an electron tube fed whose anode at the positive potential leading Wehnelt cylinder of a cathode ray tube lay. When the deflection pulses occur, the electron tube was blocked so that the normal operating condition for the cathode ray tube resulted. If the deflection pulses failed the electron tube opened and thus energized and lowered the potential of the Wehnelt cylinder,

Circuit arrangement for protection

the screen of a cathode ray tube

against overload

Applicant:

Philips Patentverwaltung GmbH,
Hamburg 1, Mönckebergstr. 7th

Dipl.-Phys. Joachim de Vos, Hamburg-Eidelstedt,
has been named as the inventor

which was connected to a voltage source via a series resistor, strong, so that the beam is blocked became. With two diodes and two electron tubes the arrangement was for both deflections effective; however, it can be seen that the effort is quite high.

It is also known to switch off the high-voltage supply device or the high-voltage supply by means of a discharge tube, the control electrodes of which are supplied with opening voltages which are applied to the deflection circuits are taken. If one or both deflection devices fail, the tube is then replaced by one constant bias source and - if necessary with the help of a relay ■ - the high voltage source switched off. Such an arrangement requires considerable effort and an accurate one Adjustment of the counterbalanced biases, and the use of mechanical Relay has other disadvantages and is costly.

The described attempted solutions all have the disadvantage that auxiliary voltages for the voltage At least one additional tube, such as basic bias or anode voltage or the like, is required are, in the event of failure, the protective device can no longer be effective, so that the damage to the cathode ray tube can still occur, especially if there are faults in the heating circuit of the Auxiliary tubes occur.

There is also already a known facility in which the DC voltage component created at a resistor by the deflection oscillations supplying tube flowing current pulse sequence of the reverse voltage of a beam current regulating

809 557/349

Electrode counteracts. However, only one deflection generator is used for backup, and because the DC component is used, there is a galvanic coupling between the deflection generator and jet control circuit necessary, which gives rise to difficulties.

It is also known to increase the number of pulses taken by the deflection devices to ensure that the beam can only occur when the deflectors are in action. Such circuits are well suited for oscilloscopes, but not for televisions, because there is also a modulation here the beam intensity and very clean pulse heads would be necessary to avoid any interference to bring about the brightness in individual image zones. It can also be brightened up by using the difficult to get a shield protection circuit, which on disturbances both as also responds to the other deflection device and works stably.

Another known protection circuit for oscilloscopes uses a negative deflection voltage Via a series resistor and a limiter diode of the cathode of the cathode ray tube connected to the Ouerzweig supplied so that during the presence of the negative deflection voltage, an opening voltage for the electron beam is obtained. However, this arrangement implies a special one Type of deflection voltage ahead and does not allow a protection of the cathode ray tube versus the failure of each of the deflection devices alone, as is the case in practice, especially with projection televisions higher performance, is important.

Finally, a circuit arrangement is known in which when one or both of the deflection voltage supplying tilting tubes are not yet working, but their anode supply voltage is already available, A circuit is closed via at least one glow tube, in which there is a resistor to which Amperage influencing electrode of the cathode ray tube is applicable.

The opening voltage drops not only in the event of disturbances in the deflection circuits, but also in the event of disturbances in the heating circuits of the diodes. Special auxiliary voltages are not required, so that the The intended protective effect is certain to occur with every possible malfunction. Also is the effort of only two diodes and a few resistors and possibly smoothing capacitors is remarkable small, and mechanical parts such. B. Relays are not necessary. The combination of the distraction circle Taken voltages can be brought about by series connections and / or parallel connections will.

Preferably, the two DC voltages are peak rectified by means of two diodes of the recoil pulses of the vertical and horizontal deflection circle obtained and feed into the Adjustment of the beam intensity serving potentiometer * at its tap z. B. the Wehnelt cylinder is connected.

If changes in the height (amplitude) of the kickback pulses are to be feared, which exceed the Protection voltages of a control electrode could interfere with the strength of the electron beam, can (can) in a known manner for the limitation (stabilization) parallel to a part or the whole Value of the protection voltage (s) one or more biased diodes can be arranged. Naturally Such a limitation can also already be applied to the deflection circuits supplied to the rectifier arrangement removed stresses are effected.

Since the voltages taken from the deflection bar can be relatively high compared to the Voltage to be supplied to the intensity control electrode can be useful, at least the magnitude of one of the DC voltages, preferably by means of a voltage divider, before it is supplied

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then a voltage drop occurs which, as a blocking voltage, is reduced to the radiation intensity potentiometer, tion of the control path of the cathode ray tube is fed.

Since the reverse voltage must first be generated in the event of a fault, it is tied to the prerequisite that in any case the necessary circuit is still functional, especially the anode voltage is available. Since the generation of the reverse voltage is only indirectly dependent on the function of the tilt tube depends, but not directly on the effectiveness or ineffectiveness of the electron beam deflection, general safe protection cannot be achieved with it.

In the present circuit arrangement, in which to protect the fluorescent screen of a cathode ray tube against overload in the absence of vertical or horizontal beam deflection, the achievement of the in normal operation of the tube required beam current intensity to the existence of the sum voltage of the output voltages of two rectifier circuits, one of which is the vertical and the other belonging to the horizontal deflection circuit is, according to the invention, with a simple one Arrangement a safe effect both in the case of failure of a deflection device alone as well as in the event of failure of all deflection devices achieved by dimensioning the two rectifier circuits in such a way that their output voltages result in a total voltage that may be subject to a voltage division, which is so large that it can be used without the involvement of others The embodiment illustrated in the drawing, which shows parts of the output stage of a television receiving arrangement.

The anode of the image signal output amplifier tube 1, which is known, but not shown in detail Way is switched and controlled and via a working resistor 2 to the positive pole is connected to a supply voltage source, not shown, controls via a galvanic coupling the cathode of a display tube 3, whose Wehnelt cylinder with a circuit arrangement according to the invention for protecting the screen of the cathode ray tube connected is.

An alternating voltage taken from the horizontal deflection circuit, preferably the kickback pulse voltage, is fed to the diode 6 via a decoupling resistor 5 via the terminal 4. A DC voltage then occurs at the resistors 7, 8 and 9 connected in the cathode circuit of this diode, which is smoothed by a charging capacitor 10.

An alternating voltage taken from the vertical deflection circuit is also applied via terminals 11, expediently also the return pulse voltage, via a decoupling resistor 12 of the diode 13 and a second occurs at the resistors 9 and 14, which are connected to the cathode circuit DC voltage generated by a capacitor 15

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Voltages as electrode voltage of a beam 7 ° is smoothed. Resistors 7, 8, 9 and 14 are

dimensioned so that the wiper of the variable resistor 8 has a potential during normal operation of the device has, which is due in approximately equal parts from the horizontal as from the vertical deflection circle and has such a size that with the wiper of the resistor 8 the usual control range for the Setting the basic brightness of the display tube 3 can be swept over.

The discharge time constants of the two rectifier circuits are also determined in particular by dimensioning of the capacitors 10 and 15 selected so that peak rectification occurs, but in the event of a fault in the deflection circuits or in the heating of the diodes 6 and 13, the one on the Wehnelt cylinder Voltage decreases so quickly that damage to the screen can be avoided.

If necessary, between the wiper of the potentiometer 8 and the Wehnelt cylinder of the tube 3 known means for further smoothing the bias may be inserted. This connection can also still in a manner known per se with capacitances and / or inductances and / or resistances be connected together, with the help of which the tube is supplied with 3 pulses to darken the beam return will. However, the above-mentioned condition for the maximum discharge time constant of the Wehnelt bias must also be taken into account will.

If one of the deflection circuits or the heater for diodes 6 and 13 fails, it discharges with the by the dimensioning determined time constant of the associated charging capacitor 10 or 15, and the Potentials of the potentiometer 8 against the negative pole (earth) go back to such values that the In every position of the controller 8, Wehnelt cylinder receives a bias that is opposite to the voltage the cathode of the cathode ray tube 3 is negative enough that the electron beam is practically blocked, in any case, however, is reduced to a harmless level.

Claims (6)

Claims 1. Circuit arrangement in which to protect the fluorescent screen of a cathode ray tube against overload in the absence of vertical or horizontal beam deflection, the achievement of the in normal operation of the tube required beam current strength to the presence of the Total voltage of the output voltages of two rectifier circuits is bound, of which the one of the vertical deflection circuit and the other of the horizontal deflection circuit, characterized by such a dimensioning of the two rectifier circuits that their output voltages an optionally result in a voltage division subject to a total voltage which is so large that it without the use of voltages other than the electrode voltage of one that influences the beam current intensity Electrode of the cathode ray tube is applicable. 2. Circuit arrangement according to claim 1, characterized by two DC voltages which preferably by means of two diodes by tip alignment of the return pulses of the vertical and the horizontal deflection circle are obtained and the one for adjusting the beam intensity feed the serving potentiometer at which the opening voltage for the strength of the Electron beam influencing electrode is removed. 3. Circuit arrangement according to claim 1 or 2, characterized in that the deflection circuit Taken and rectified voltages are limited in amplitude. 4. Circuit arrangement according to claim 2, characterized in that at least the size one of the direct voltages before being fed to the beam intensity potentiometer, preferably by means of a voltage divider is reduced. 5. Circuit arrangement according to claim 1, 2 or 3, characterized by a duo diode for Rectification of the voltages taken from the deflection circuits. 6. Circuit arrangement according to one of the preceding claims, characterized in that the time constants of the rectifier circuits are dimensioned so that if the vertical and / or horizontal deflection the reduction of the jet current within the time span, during which the screen is loaded with the undeflected electron beam may be carried out. Considered publications: German Patent Nos. 687 541, 699 364; French Patent No. 789,987; U.S. Patent No. 2,567,861; Klein, electron beam oscilloscope, Berlin 1948, Vol. 1, p. 130; La T. S. F. pour tous, Vol. 27, 1951, No. 278, p. 397 to 399. 1 sheet of drawings © 809 557/349 6.