DE2211189A1 - Automatic degaussing device for a color television tube - Google Patents

Description

734-0-72 / Kö / S
RCA Docket No. 64222
Convention Bate:
March 8, 1971

RCA Corporation, New York, N.Y., V.St.A.

Automatic degaussing device for a color television

picture tube

The invention relates to an automatic degaussing device for a color television picture tube with a first AC voltage source, with which the series connection of a degaussing coil and a temperature-dependent resistor is connected in parallel, and with a second AC voltage source.

In the case of a shadow mask color picture tube, the metallic hole mask or shadow mask and its holder are together with others Metal parts of the tube the most diverse magnetizing influences, for example, during transportation to the user's home and during home use. Such an undesirable Magnetization comes about when the picture tube is placed in the vicinity of magnetizing fields, such as those found in transport vehicles, Elevators and the like. Occur, or in use, for example, comes under the influence of the earth's magnetic field. Such random magnetization often affects the performance of color television receivers.

To remedy this, demagnetization is provided. Automatic demagnetization is often provided for the color television picture tube, which is usually carried out with the help of a coil

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Order takes place, which is appropriate in such a way that the the field generated by it, the shadow mask and its ^ mounting, included in the picture tube. The coil arrangement is fed with alternating current, which is initially of considerable magnitude and then gradually decreases to a residual current of relatively small size. Many circuits for feeding or exciting such Coil assemblies use circuit elements such as thermistors and varistors to depress the coil current and the coil assembly effectively disconnect from the AC power source, after the excitation current has dropped to the relatively low residual current value.

A problem encountered with many circuits of this type is that the weak residual current is often still sufficient to impair the image reproduction on the screen gen. In what way the picture is affected depends on the Size of the residual current and the spatial dimensions of the coil arrangement and its arrangement in the receiver. One kind of possible impairment or deterioration of the image reproduction consists in the appearance of a series of thin horizontal lines, when playing a color broadcast slowly in the vertical direction wander across the screen of the picture tube. . ", ..,

It is known the residual current in the degaussing coil to minimize this by placing a thermistor in series with the degaussing coil via an AC voltage source switches, being the connection point of the thermistor and the degaussing coil is connected to another AC voltage source via a resistor. The circuit elements and the operating voltages are dimensioned in such a way that when the steady-state operating state is reached (when the thermistor has reached its operating temperature is heated) the voltage division between the thermistor and the resistor is essentially the same voltage gen at both ends of the degaussing coil. This will reduce the voltage gradient across the degaussing coil and consequently the residual current flow in the degaussing coil is reduced. In this way, the residual current can be reduced but jagged current pulses can still occur.

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occur when the - on the thermistor and on the degaussing coil AC voltage contains high-frequency components.

High frequency components often appear in the secondary winding circuit of the power transformer of television receivers, even then when the primary winding is fed with a pure sinusoidal voltage, because the secondary winding is through circuit elements, specially diodes are loaded, which, when they are biased into the conducting and into the blocked state, abrupt changes in the Cause secondary voltage curve, so that high-frequency components are generated. This is particularly uncomfortable with television receivers with "cold chassis", i.e. with television receivers Trennixansf or mat or. With such recipients one sees to the danger to keep an electric shock as low as possible, automatic Demagnetization circuits on the secondary winding side of the mains transformer of the television receiver in front of where high frequency Components can occur.

The invention is based on the object of the residual current flow in the degaussing coil of a television receiver in the stationary Minimize operations.

An automatic degaussing device is used to solve this problem of the type mentioned according to the invention, characterized in that a frequency-dependent impedance element in Series with the temperature-dependent resistor to the second AC voltage source is coupled in such a way that, when the temperature, temperature-dependent resistance has its steady work value, on Connection point of the temperature-dependent resistor and the degaussing coil a voltage is generated which reduces the voltage drop across the degaussing coil and thus the residual current flow in the degaussing coil.

The invention is described below with reference to the drawings in individually explained. Show it:

Figure 1 shows the circuit diagram of a degaussing 'according to the invention sierungseinrjchtungj and

Fig. 2 is a diagram useful for understanding the various

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Invention serving voltage and current curves reproduces.

In FIG. 1, a voltage, for example an alternating voltage of 120 volts and 60 Hz, is applied to terminals 12-12 ', which are connected via a switch 14 to the primary winding 16 of an iron-core transformer 20 be. The voltage generated at the secondary winding 24 of the transformer 20 is processed in a half-wave rectifier 27 to a direct voltage of +225 volts for use in the television receiver 22. The secondary winding 24 has a tap 26 which, like the end 28 of the secondary winding 24, is connected to a full-wave rectifier bridge 30 in order to obtain a direct voltage of +160 volts for use in the television receiver 22.

Between the tap 26 and the end 28 of the transformer secondary winding is the series connection of a degaussing coil 32 and a temperature-dependent resistor 34 with a positive Coefficients switched. Temperature-dependent resistances with positive coefficient are thermistors whose resistance is with as the temperature rises, as occurs when current flows through the thermistor. The connection point 36 of the temperature-dependent Resistor 34 and the degaussing coil 32 is connected via the parallel connection of a resistor 38 and a capacitor 40 to the end 42 of the secondary winding of the transformer 20 connected.

When the switch 14 is closed, a sinusoidal voltage is applied to the primary winding 16 of the transformer 20, as shown in Figure 2a. A distorted one appears between the tap 26 and the end 28 of the secondary winding 24 of the transformer Sinusoidal voltage as shown in Figure 2b. A distorted sinusoidal voltage of a similar shape but with a larger amplitude appears between the ends 28-42 of the secondary winding 24. Since the temperature-dependent resistor 34 is initially cold (ahead given that switch 14 has been open for a sufficiently long time before closing) flows between the taps 26 and the end 28 of the transformer secondary winding a relatively strong current through the series connection of the demagneti -

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Sizing coil 32 and the temperature-dependent resistor 34. In addition, a current flows through the series connection of the temperature-dependent winding between the ends 42 and 28 of the transformer secondary winding Resistor 34 and the RC parallel link 38,40.

As a result of the current flow through the temperature-dependent Resistor 34 begins to heat up, with its resistance value increases. Because of the increasing resistance value of the temperature-dependent resistor 34, the current flow is reduced between the tap 26 and the end 28 of the transformer secondary winding. Consequently, that also begins with demagnetization ^ coil 32 generated magnetic field, so that a demagnetizing effect on the shadow mask and mask holder (not shown) of the picture tube of the television receiver.

With increasing resistance value of the temperature-dependent Resistor 34 starts the voltage at junction 36 due to the voltage sharing between capacitor 40 and the Resistances 38 and 34 to increase. This reduces the voltage gradient across the degaussing coil 32 between the Tap 26 of the transformer secondary winding and the connection point 36. As a result, the current flow in the degaussing coil increases 32 from. When the temperature-dependent resistor 34 its stationary working temperature and its stationary Reached the working resistance value prevail at the tap 26 of the transformer secondary winding and at the connection point 36 substantially the same voltages, so that the residual current flow in the degaussing coil 32 is very low.

As can be seen from Figure 2b, the voltage is between the tap 26 and the end 28 of the secondary winding 24 of the transformer a distorted sine wave voltage. The vertex 44 of the Tension are essentially flat, and the initial course 46 of the descent from apex 44 to the abscissa is substantial vertical. These distortions result from the loading of the secondary winding 24 by circuit elements of the television receiver 22. The flat parts 44 result from the current line of the diodes of the half-wave rectifier circuit 27 and the full-wave rectifier

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Richter bridge 30, while the vertical parts 46 are switched off of the diodes.

Due to the distortion of the voltage on the secondary winding 24 of the transformer 20 compared to the pure sinusoidal shape high-frequency signal components. This in the secondary circuit of the transformer 20 occurring high-frequency signal components found in the shunt capacitance of the temperature-dependent Resistance 34 a low-resistance way. This is particularly evident from FIG. 2c, which shows the residual current flow in the Degaussing coil 32 in the steady operating state with the resistor 38 and capacitor 40 omitted. Of the Residual current has a distorted sinusoidal shape with jagged current pulses 48. These current pulses are due to the flow of the hochfre quent signal components through the degaussing coil 3 2 and the parallel or shunt capacitance of the temperature dependent resistor 34 conditional.

If the resistor 38 (but not the capacitor 40) is inserted into the circuit, flows as a result of a decreased Reduce the voltage gradient of the fundamental frequency signal component The residual current in the degaussing coil. This can be seen in Figure 2d, where the residual current flows in the degaussing coil 32 is shown in steady-state operation with the resistor 38 inserted into the circuit (but without the capacitor 40). However, the parallel capacitance of the temperature-dependent resistor 34 forms a low-resistance conduction path for the high frequency quenten signal components, and there remains a voltage gradient of these high-frequency signal components at the demagnetization ^ coil 32 exist.

Since the temperature-dependent resistor 34 has a voltage-dependent characteristic, its resistance value changes at Change in the voltage at junction 36. As a result, the voltage dividing ratio between resistor 38 changes and the temperature-dependent resistor 34, so that at the temperature-dependent resistor 34 harmonic-frequency voltage components occur at the tap 26 of the secondary winding of the Trans

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formators 20 are not available. As a result, there is a voltage gradient at the degaussing coil 32, so that a residual current flows even when the high-frequency signal components are not present. However, due to the voltage gradient of the harmonic-frequency voltage components at the Degaussing coil 32 caused residual current not so great that he is disturbing. In contrast, the harmonic-frequency voltage components combine with the high-frequency signal components while generating a residual current (Figure 2d), which in its shape and in its current zero crossings is different from the current curve according to FIG. 2c. The harmonic frequency voltage components and the high-frequency signal components unite in the absence the fundamental frequency signal component in such a way, that a voltage gradient arises at the degaussing coil 32, as the size of the serrated residual current pulses 50 increases. The size of the residual current pulses 50 is sufficient to reproduce the image affect on the screen of the picture tube. The impairment or disorder can take the form of the already make the mentioned thin horizontal lines noticeable, which slowly migrate vertically across the screen.

The arrangement of the capacitor 40 in connection with the resistor 38, the residual current peaks can be significantly reduced. The current curve shown in Figure 2e gives the residual current flow in the degaussing coil 32 again in the event that the resistor 38 and the capacitor 40 are inserted into the circuit in the manner shown in FIG. Although the Residual current course still zigzag-shaped current peaks or -impulses 52, which, however, are considerably smaller in their amplitude than the residual current spikes in Figure 2d, so that the image reproduction is accordingly better. The capacitor 40 acts as a frequency compensation element, by compensating for the effects of the parallel capacitance of the temperature-dependent resistor 34. Because of the presence of the capacitor 40, high-frequency signal components with a larger amplitude can reach the connection point 36 are coupled, reducing the voltage gradient of the high-frequency Signal components at the degaussing coil 32 themselves

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decreased and thus the residual current spikes in the demagnetization ^ coil can be reduced in size.

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Claims (7)

Claims (l / Automatic degaussing device for a Color television picture tube with a first AC voltage source, with which the series connection of a degaussing coil and a temperature-dependent resistor is connected in parallel, and with a second AC voltage source, thereby characterized in that a frequency-dependent impedance element (38, 40) is coupled in series with the temperature-dependent resistor (34) to the second AC voltage source (42, 28) is, such that when the temperature-dependent resistance has its steady working value, at the connection point (36) of the temperature-dependent resistor and the degaussing coil (32) a voltage is generated that the voltage gradient across the Degaussing coil and thus the residual current flow in the degaussing coil belittles. 2. Demagnetizing device according to claim 1, characterized in that the frequency-dependent Impedance element contains a capacitor (40). 3. Demagnetizing device according to claim 1, characterized in that the frequency-dependent Impedance element consists of the parallel connection of a resistor (38) and a capacitor (40). 4. Demagnetizing device according to one of claims 1 to 3, characterized in that the from the first AC voltage source (26, 28) supplied voltage and the voltage supplied by the second AC voltage source (42, 28) Voltage .j'eW-rush have a distorted sinus shape « 5. Demagnetizing device according to one of the preceding claims, since by gek β η η ζ calibrated η et that the erete exchange fault source (26, 28) through the one »end (28) vtnä a tap (26) of the secondary winding <24) 209839 / 083Ö Transformer (20) is formed that the temperature-dependent Resistance (34) and the frequency-dependent impedance element (38, 4f | connected in series between one end (28) and the other end (42) of the secondary winding of the transformer; and that the degaussing coil (32) between the tap (26) of the secondary winding of the transformer and the connection point of the frequency-dependent impedance element and the temperature-dependent Resistance is switched. 6, degaussing device according to claim 5, characterized in that the temperature-dependent Resistor (34) is a temperature-dependent resistor with a positive temperature coefficient of resistance. 7. degaussing device according to claim 5 or 6, characterized in that the secondary winding (24) of the transformer (20) is connected to a rectifier circuit (27) is coupled to generate a rectified voltage for the television receiver (22). 209839 / Ö83Q Blank page