DE3415788A1 - Protective circuit for television picture tubes - Google Patents

Abstract

Known protective circuits are used for monitoring the existence of synchronisation pulses or deflection voltages present at the deflection coils. If an interruption occurs in the deflection circuit, this is not reliably detected so that there is a risk of damage to the picture tube. The present invention prevents this problem in that signals which are compared with a reference voltage are obtained from the deflection currents. If the currents drop below a predetermined value, the electron beam of the picture tube (BR) is cut off which protects the tube against burn-in. The invention is applied in television display devices with magnetic deflection. <IMAGE>

Description

Protection circuit for television picture tubes

The invention relates to a protection circuit for television picture tubes according to the preamble of claim 1.

From the book "Fernsehempfangstechnik - Schwarzweiß und Farbe" by M. Koubek, Franzis-Verlag Munich, 1969, pages 266 to 268 are protective circuits known for television picture tubes with magnetic deflection, in which the presence is monitored by sync pulses. If the sync pulses fail, a reverse voltage is applied given to a control grid of the picture tube, which darkens the picture tube. It will So it is assumed that as long as sync pulses that make up the deflection currents for the picture tube are derived, are present, the electron beam is also deflected will. However, it can happen that despite the presence of sync pulses or Deflection voltages the electron beam is not deflected and therefore the luminescent layer the picture tube is damaged if the feed line to the deflection coils is interrupted is.

This risk exists e.g. B. when the deflection coils are rotatable and the supply lines are routed via sliding contacts.

The present invention is based on the object of a protective circuit for television picture tubes with magnetic deflection that also work when interrupted the feed line to the deflection coils responds and the picture tube reliably counteracts Burn-in protects.

According to the invention, this task with the in the characterizing part of claim 1 specified circuit measures solved.

With the new protective circuit, the voltages on the deflection coils are not and also not the sync pulses from which the deflection voltages are generated, monitored, but directly the deflection currents flowing through the deflection coils. An interruption of the deflection current, e.g. B.

due to a faulty sliding contact, leads directly to switch off the electron beam.

Both the horizontal and the vertical deflection current are expedient taken into account for switching off the electron beam. This can be done from the two If a DC voltage corresponding to the current sum flows in a diode adding circuit generated and compared with a reference signal. That from the comparison The signal obtained can be the signal controlling the brightness of the displayed image are superimposed.

Another embodiment of the invention in which the protection circuit for the picture tube and the circuit for brightness control expenditure-lrm summarized is that those corresponding to the horizontal and vertical deflection ducts Signals are fed to a transistor in such a way that if a signal fails, the Transistor is blocked. The transistor is the control electrode of the picture tube connected downstream that, when the transistor is switched on, the desired Operating point of the picture tube receives the required voltage and with the transistor blocked the beam current of the picture tube is blocked.

The transistor thus serves as an AND gate, which only then feeds the beam current the picture tube emits released signal when both the horizontal deflection wi is the signal corresponding to the vertical deflection current with a minimum amplitude is available. A constant current source or with the transistor is advantageous the output current of a constant current source is switched. The collector-emitter can be used for this purpose of the transistor connected in series with a constant current. In order to will achieved that when the constant current crosses a resistor is performed, at this a constant voltage as a control voltage for the picture tube brightness can be removed. As a supply voltage for the power source or for the Series connection of the current source and the transistor can result in the vertical deflection current or preferably the signal corresponding to the horizontal deflection current and one serve further tension.

With reference to the drawing, refinements of the invention are shown in the following described and explained in more detail.

There show Figure 1 an embodiment of the invention with a Adding stage which adds the signals corresponding to the deflection currents, FIG 2 shows an embodiment of the circuit according to FIG. 1, FIG. 3 shows an exemplary embodiment, in which the protective circuit for the picture tube and the circuit for brightness control the picture tube are combined with little effort.

In Figure 1, HAS denotes a horizontal deflection circuit, feeding a pair of HSP horizontal deflection coils.

A transformer HTR is connected to the current path and has a secondary winding on it a potentiometer P1 is connected to which a corresponding to your Horizonttlablezkstrom Tension occurs. The partial voltage determined by the potentiometer setting reaches a rectifier GL1 via a capacitor C1, to which one input an adder ADD is connected.

The output amplifier VAS of a vertical deflection circuit, which the Supplying current for a pair of vertical deflection coils VSP is with a sawtooth voltage controlled. Thus the time course of the vertical deflection current with that of the input sawtooth voltage corresponds, a current counter £) 1utlgswiderstand is provided, which in the example as Potentiometer GKP is designed. The voltage drop across this is applied to the inverting input of the amplifier fed back, so that the current of the sawtooth-shaped Control voltage is tracked. The one occurring at the tap of the GKP potentiometer Partial voltage reaches a rectifier GL2 via a capacitor C2, to the the second input of the adder ADD is connected. L. At its exit occurs thus a signal that is the sum of the horizontal and vertical deflection currents is equivalent to.

This sum signal is in a comparator VGL-with one with one Potentiometer P2 set reference voltage compared. A level converter is attached to this PUS connected, the output voltage of which is transferred to the Control grid G1 of the picture tube BR is performed. This is also the output voltage a brightness control circuit HLS supplied, which tielligkeitsroller with eii1eia HR is adjustable. The level converter PUS is used to convert the output voltage of the comparator VGL to such values that when the output voltage of the adder ADD is greater than the reference voltage set with the PotentiomeXer P2, the diode D1 blocked and thus only the signal from the brightness control circuit HLS on the grille G1 is effective and that when the output voltage of the adder ADD is unreliable as a result Drop in one of the deflection currents is less than the reference voltage over which Diode D1 sends a signal blocking the electron beam of the picture tube BR to the control grid G1 is given. The output of the level converter PUS is compared to that of the Brightness control circuit HLS low resistance, so if a deflection current fails the picture tube BR safely blanked regardless of the brightness set will.

Figure 2 shows a circuit in which the rectifier for the Deflection currents corresponding voltages and the adder are combined. With P1 and P2 are the potentiometers on which the deflection currents appropriate Signals occur. The voltage at the tap of the potentiometer P2 is in a full wave rectifier circuit D4, D5 rectified and clamped to a voltage U at the same time. On a capacitor C3 thus occurs a voltage which is equal to the sum of the voltage U and the rectified Tension is. The voltage at the tap of the potentiometer P1 is in a full wave rectifier circuit D2, D3, C4 rectified so that a signal is fed to the comparator VGL, that of the sum of the signals picked up by the potentiometers P1, P2 and the voltage U corresponds to.

An input E1 of the circuit according to FIG. 3 is a vertical current corresponding signal supplied. For this purpose, the input El can be used like the rectifier GL2 of the circuit according to FIG. 1 is connected to a current negative feedback resistor which is in series with the vertical deflection coils. The one fed to the entrance El Signal is amplified by an amplifier V1 and in a rectifier GL3, the a smoothing capacitor C5 is connected downstream, rectified. At the base of one Switching transistor TS1 thus occurs a DC voltage that the vertical deflection is equivalent to. As long as the amplitude of the vertical deflection current has a minimum size, the transistor TS1 is turned on, which then in turn via a resistor R1 gives a control voltage to the base of a pnp transistor TS2. The positive one Supply voltage of the transistors TS1, TS2 is rectified by one Formed signal that is fed to an input E2 and the horizontal deflection is equivalent to.

As in the circuit according to FIG. 1, this can be done on the secondary winding a transformer, whose primary winding is connected to the horizontal deflection coils is connected in series. It is less time-consuming to generate the signal on the so-called tangent capacitor to tap into the circuits already present in television playback devices for pillow equalization is included. This Signal goes to a rectifier GL4 supplied. Its output signal, smoothed in a capacitor C7, serves as the positive supply voltage for the transistor TS1 and a series circuit, existing from a current source 10 with a transistor TS3 and the transistor TS2. For education the negative supply voltage of the transistor TS2 will be that of the flyback transformer recoil pulses that occur are fed to a rectifier GL2 via an input E3, which a resistor R2 and a Zener diode Z are connected downstream, so that at one A stabilized supply voltage is applied to capacitor C7. The collector resistance of the transistor TS2 is formed by a potentiometer P3, at its tap the grid Gl of the picture tube is connected. This potentiometer can therefore the image brightness can be adjusted.

In normal operation of the television display device, if the vertical and the horizontal deflection current and the flyback pulses each in sufficient Amplitude are present, so are the positive and negative supply voltages for the series connection of the constant current source 10 and the transistor TS2 available, and the transistors TS1 and TS2 are turned on. Accordingly, flows over the Potentiometer P3 a constant current, so that the grid G1 of the picture tube has a constant Receives control voltage, which results from the Zener voltage of the Zener diode Z and the voltage drop at the lower partial resistance of the potentiometer P3. Becomes the vertical deflection circle interrupted, so that the signal at the input El fails, the transistors TS1 and TS2 blocked, and the grid G1 receives a negative voltage, which is approximately is equal to the Zener voltage, so that the beam current of the picture tube is blocked. If the signal at input E2 fails, the positive supply voltage breaks Capacitor C6 together, so that also the negative Zener voltage to the grid G1 reached. If one of the two deflection currents fails, the high-voltage tion the picture tube switched off. The capacitance of the capacitor C7 is such that when the transistor TS2 is blocked, the negative blocking voltage at the grid G1 of the picture tube is maintained at least until the anode voltage has decayed so far is that the electron beam hitting the screen will no longer damage it can.

15 claims 3 figures

Claims (15)

Patent claims Oil protection circuit for television picture tubes, their electron beam of magnetic fields that flow from horizontal and vertical deflection coils or vertical deflection currents are generated, deflected and in the event of failure of the Deflection is blocked by applying a blocking voltage to a control electrode, d a d u r c h e k e n n n z e i c h n e t that a dem horizontal and / or dem Vertical deflection current corresponding signal and that the control electrode (G1) the blocking potential is supplied when the deflection current or currents corresponding signal falls below a specified limit value. 2. Protection circuit according to claim 1, d a d u r c h g e k e n n z e i c h n e t that when using a known vertical deflection circuit (VAS, GKP) with a current negative feedback resistor that corresponds to the vertical deflection current Signal is the voltage drop across the current negative feedback resistor (GKP). 3. Protection circuit according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that in the line leading the horizontal deflection current the Primary winding of a transformer (HTR) is connected by its secondary winding the signal corresponding to the horizontal deflection current has been picked up. 4. Protection circuit according to one of claims 1 to 3, d a d u r c it should be noted that an adder stage (GL1, GL2, ADD) is present, which are the signals corresponding to the horizontal and vertical deflection currents individually rectified and added and connected to a comparator (VGL) which compares the sum signal tnit delll predetermined limit value and a blocking signal emits when the sum signal falls below the limit value in terms of amount. 5. Protection circuit according to claim 1, d a d u r c h g e k e n n z e i c h n e t that those corresponding to the horizontal and vertical deflection currents Signals are fed to a transistor (TS2) in such a way that if a signal fails the transistor (TS2) is blocked, and that the transistor (es2) has the control electrode (G1) the picture tube is connected downstream in such a way that it is switched on when the transistor receives the voltage required for the desired operating point of the picture tube and when the transistor is blocked, the beam current of the picture tube is blocked. 6. Protection circuit according to claim 5, d a d u r c h g e k e n n z e i c h n e t that with the transistor (TS2) a constant current source or the output current a constant current source (Io) is switched. 7. Protection circuit according to claim 6, d a d u r c h g e k e n n z e i c h n e t that the collector-emitter path of the transistor (TS2) with the constant current source (Io) is connected in series. 8. Protection circuit according to claim 6 or 7, d a d u r c h g e k e n n z e i c h n e t that as supply voltage for the constant current source or for the series connection of the constant current source (Io) and the transistor (TS2) das corresponding to the vertical deflection current or preferably the horizontal deflection current Signal as well as another voltage is used. 9. Protection circuit according to claim 8, d a d u r c h g e k e n n z e i c h n e t that the further voltage through rectification (GL5) from the flyback transformer removed line checkback pulses is generated. 10. Protection circuit according to one of claims 7 to 9, characterized by: a) the transistor (TS2) is a pnp transistor; b) the power source (Io) is in the emitter circuit of transistor (TS2); c) as a positive supply voltage for the series connection of the constant current source (Io) and the transistor (TS2) that corresponding to the vertical or, preferably, the horizontal deflection current Signal; d) The further voltage, which stabilizes, serves as the negative supply voltage is; e) there is a potentiometer (P3) in the collector circuit of the transistor (TS2) whose tap the control grid (G1) of the picture tube is connected. 11. Protection circuit according to one of claims 8 to 10, d a d u r c h e k e n-n z e i c h n e t that the further voltage to a capacitor (C7) is placed, the capacity of which is such that in the event of failure of the further voltage it discharges with a time constant that is at least equal to the time constant is with which the high voltage of the anode after switching off the control pulses for the high voltage unit dies away. 12. Protection circuit according to one of claims 5 to 11, d a d u r c h e k e n n n z e i c h n e t that the first control electrode of the transistor (TS2) a switching transistor (TS1) is connected upstream. 13. Protection circuit according to claim 1, d a d u r c h g e k e n n z e i c h n e t that when using a known vertical deflection circuit (VAS, GKP) with a current negative feedback resistor that corresponds to the vertical deflection current The signal is the voltage drop at the current negative feedback resistor (GKP). 14. Protection circuit according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that in the line leading the horizontal deflection current the Primary winding of a transformer . (HTR) is switched, of its Secondary winding the signal corresponding to the horizontal deflection has been removed. 15. Protection circuit according to one of claims 1 to 13, d a d u r c it should be noted that the corresponding to the horizontal deflection current Signal from the pincushion equalization serving tangent capacitor is removed.