DE2211189C3 - Automatic degaussing device for the picture tube of a color television receiver - Google Patents

Description

A voltage-dependent distribution of voltage between the _temperature- dependent resistor and the other resistor arise. The impulse mushrooms formed from these two stresses arise

f That screen as slow vertically above this one horizontal lines disturbing noticeable.

The object of the present invention is

in the inadequate wedges of the well-known F.nt-

"Eliminate n'etisierungsschallungen and a

Denial of the sound of the question

abolish which with simple means the im-

ulsspilzc. » or the Reslstromwerl on the Enimagnelisicrungsspule in the steady state presses to a negligible minimum.

According to the invention, this problem is solved by attenuating the temperature-dependent contradiction caused by the temperature-dependent contradiction in continuous operation in the indus. ■■ Superposition of harmonics of the alternating waves: ,, uhccü with high-frequency signal components aui;: -, - t-end-e ·. | _nl p _U lssp;: voltages parallel to the other V. "nL ·: - » land a capacitor is connected . n .;;: i pensation. by compensating for the effects of the ParalMk -,: - .: ■■ city de, temperature-dependent resistances ·., k-. Due to the invention: i: '' ep Konder. -: -. i '»rs high-frequency signal ... iriponenien!" .- u of greater amplitude at the \ ei h: n-.kin .: point zv-.isehen the temperature-dependent;: ΐ · ά, icni others ·· . Resistance to be placed, whereby. ι: the voltage gradient of this high-frequency sign.! .. ■ .m; ¹ ·>nentei; in the magnetizing coil and the remnants in the magnetizing coil are reduced in size. The disturbing horizontal lines; on the ¹ screen are avoided with the simple circuit.

Advantageous configurations of the circuit according to the invention are given in the

The invention is hereinafter referred to animal Drawings explained in detail. Is shows

f- i g. 1 the sonic shame of an inventing genius En'magnelization device, and

F i ιΓ. 2 is a diagram showing various understanding the invention serving Sp.innungs- and power running s represents.

In F ι '- ■ 1 is connected to terminals 12, 12' of a Eiseiikeintransformalors 20 are connected via a switch 14 to the primary winding 16, a voltage such as an AC voltage \ on 120 full "and 60 Hz, the transformer 20 can. the mains transformer of a television receiver 22. 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 Vollwci ^ ieidirichlcrbrücke 30 in order to gain a direct voltage of < HiO volts for use in the television receiver 22.

The series connection is between the tap 26 and the end 28 of the transformer secondary winding a demagnification coil 32 and a teinpcralur-dependent Widcrslands 34 with positive coefficient switched. Temperature-dependent resistances with a positive coefficient, thermistors are those whose resistance to increasing temperature is like it occurs when current flows through the thermistor, increases. About connection point 36 of the temperature-dependent Resistance 34 and the Demagneusierunu, spule32 is via the parallel connection of a resistor 38 and a capacitor 40 with clem End 42 of the secondary winding of the transformer 20 connected. ,

If the switch 14 is Eesch5os.cn, there is a sinusoidal voltage on the primary winding 16 of the transformer 20 as in FIG. 2 α shown. A distorted sinusoidal voltage appears between the tap 26 and the end 28 of the secondary winding 24 of the transformer, as in FIG . 2b shown. 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 (provided that the switch 14 has been open for a sufficiently long time before closing ), a relatively strong current flows between the tap 26 and the end -H of the transformer secondary winding through the series connection of the, c HntmauneiiNierunaxspule 32 and the temperature-dependent resistor 34. In addition, a current flows through the series connection between the "42 and 28 of the transformer secondary winding of the tcmperalurependent resistor 34 and the KC'-parallel ghcdes 38 ^ 40.

Ms I-olue of the current flow through the tempcraturablKiimieen Resistor 34 begins to heat up, whereby its resistance value increases. Wecen the increasing contradiction value of the tcmpe- «iature-dependent resistance 34 decreases the 'Slro.nlluss wipe the tap 26 and the end 28 of the transformer secondary winding. Hence it begins also to remove the Masinelfeld produced by the detuning coil aui the shadow mask and masking (not shown) of the picture tube of the Television receiver is exercised.

With increasing resistance value of the tcmperalu, dependent resistance 34, the voltage 4- begins. at the connection point 36 due to the voltage line between the capacitor 40 and the resistors 38 and 34 to rise. This reduces the voltage drop across the demagnetization coil 32 between the tap 26 of the transformer secondary winding and the connection terminal 36. As a result of this, the slronillulf in the Fnlmaunetisierungsspule 32 decreases. When the temperature-dependent resistor 34 reaches its steady-state working temperature and its steady-state working resistance, the voltages at the tap 26 of the transformer secondary winding and at the connection point 36 are essentially the same, so that the residual flow in the demagnification coil 32 is very low.

As from Fig. 2b, the voltage between the tap 26 and the linde 28 of the secondary winding 24 of the transformer is a distorted sine span. The apex 44 of the voltage are substantially! Laughing, and the initial Ver-6 ₅ run 46 of the Abslieus from the apex 44 to the abscissa is substantially vertical. These distortions result from the loading of the secondary winding by circuit elements of the television receiver 2-.

The flat parts 44 result from the power line the diodes of the semi-parallel acoustic signal 27 and the full-way bridge 30, while the Vcrtikaltcile 46 result when the diodes are switched off.

Due to the distortion of the voltage on the secondary winding 24 of the transformer 20 opposite the pure sinusoidal shape results in high-frequency signal components. This in the secondary winding circuit de; Transformer 20 occurring high frequency Sijinalkomponenlen are found in the shunt capacitance of the tfcmperalura-dependent resistor 34 propose a low-resistance path. This is particularly evident from FIG. 2c, which shows the residual current flow in the demagnification coil 32 in the steady-state operating state with the resistance omitted 38 and capacitor 40 reproduces. The residual current has a distorted sinusoidal shape with a jagged shape Current pulses 48. These current pulses are generated by the flow of high-frequency SignalHmponcntcn by the demagnetization coil 32 and the parallel or connection capacitance of the temperature dependent Resistance 34 conditional.

If the resistor 38 (but not the capacitor 40) is inserted in the circuit, a reduced reverse current flows in the demagnification coil as a result of a reduced voltage drop of the basic frequency signal component. This is in FIG. 2d can be seen where the Rcststromfluß (but without the capacitor 40) in the Entmagnelisicrungsspule 32 in steady operation at an inserted into the circuit resistance 38 - ■ is cdergcgebcn!. The parallel capacitance of the temperature-dependent resistor 34, however, forms a low-ohmic conduction path for the high-frequency signal components, and a voltage gradient of these high-frequency signal components remains at the magnetization coil 32.

Since the temperature-dependent resistor 34 has a voltage-dependent characteristic, it changes its resistance value when the voltage at junction 36 changes. As a result, that changes Voltage division ratio between resistor 38 and the temperature-dependent resistor 34, so that voltage components occur at the temperature-dependent resistor 34 with an obcrwcllcnfrequentc which are not present at the tap 26 of the secondary winding of the transformer 20. When The consequence of this is the undermagnelization coil 32 a voltage drop so that a residual current flows even if the high-frequency signal components are not present. However, due to the voltage gradient, it is the most frequent Voltage components on the isolation coil 32 conditional reslrom is not so resentful that it bothers. In contrast, the obcrwoUenfrequcnlcn unite Voltage components with the high-frequency components Signal components with the generation of an Rc:; tstroines (Fiji. 2d), which in its form and in its sirom zero crossings from the current curve laugh F i g. 2 c is different. The harmonic frequencies Tension components and the high frc- '. Jucnien Signal components combine in the absence of the basic signal components Such a way, that a voltage gradient at the F.ntmagnetisicrungsspulc 32 occurs when the size of the jagged residual current pulses 50 increases. the The size of the residual current pulse 50 is sufficient to display the image on the screen of the picture tube affect. The impairment or disorder can be noticeable in the form of the already mentioned thin horizontal lines that run in the vertical direction wander slowly across the screen.

Through the arrangement of the capacitor «40 in connection with the resistor 38, the residual current zigzag can be reduced significantly. The in F i g. The current curve shown in 2c gives the residual current flow in the demagnification coil 32 again in the event that the resistor 38 and the capacitor 40 in the in F 1 g. 1 into the circuit are inserted. It is true that the course of the current continues to have jagged current peaks or pulses 52 which, however, are considerably smaller in their A.mp! itudc are as the residual current spikes in FIG. 2 d, so that the image reproduction is correspondingly better The capacitor 40 acts as a frequency compensation clamp. by seeing the effects of the parallel capacity de?

Temperature-dependent resistance 34 compensated. Because of the presence of the capacitor 40 high-frequency Signalkomponcntcn can with greater) amplitude to the connecting point 36 gckoppel ¹ are thereby the voltage gradient of the hochfre queiitcn signal components at the Entmagnetisic approximately spool 32 lowers, and thus the residual current-pip be nert verklci in the Enlmagnetisierungsspulc.

1 sheet of drawings

Claims (5)

ι 2 such arbitrary magnetization affects patent claims: often the performance of color television receivers. 1. Enlagnetization circuit for the picture IJm to remedy this, one provides an Enlmagnet tube of a color television receiver with an im 5 tization. Often an automatic Enlmagneti continuous operating condition balanced bridging provided for the color television picture tube, the sound, one branch of which is carried out through two in series, usually with the help of a coil arrangement, switched AC voltage sources and their which is attached in a suitable manner so that the Another branch through the series connection of a field generated by it, the perforated mask and its holding perimeter dependent Resistance with an io tion in the picture tube includes. The other magnetizations Opposition is formed and in their guiding coils are fed with alternating current, the Diagonal form a degaussing coil gradually from a relatively large initial amplitude let 1st, characterized in that a residual current is relatively small in size for dampening of the demagnification sinks. Lots of circuits to power lntspule (32) circuit elements are used in the case of magnetization coils in permanent operation borrowed temperature-dependent resistance (34) as well as temperature-dependent resistances and varistor sequence of superimpositions of harmonics of the ren in order to reduce the coil current and the coil voltage to effectively switch off from the AC power source with high-frequency signals, components occurring pulse voltages after the excitation current is paralleled to the residual current the other resistor (38) is a 20 sunken. Capacitor (40) is connected. One that occurs in many circuits of this type 2. De-niagnosis circuit according to the problem is that the weak residual current Claim 1, characterized in that the skin is still sufficient to reproduce the image. Selspannungsquellen (26, 28; 26, 42) to affect distorted on the screen. It is be-sine alternating voltages deliver. 25 knows. the residual current in the degaussing coil 3. Entniagnetisierung towards An to vciringcrn that one tcmperaturspruch 1, characterized in that the two dependent resistance in series with the Kntmagneti-Wechselclspannungsquellen in series connected sierungsspule over an alternating voltage source switches secondary windings of a transformer (20), whereby the Vernmdungspunkl des tempera are. ₃ o independent resistance and demagnelization 4. De-magnetization circuit after the start-up coil via a resistor to another Claim 1, characterized in that the tem- AC voltage source is connected. The temperature dependent Resistance has a positive tuimselemenle and the operating voltages are like that Temperalurkoefli / ienten has. dimensioned so that when the steady-state operating 5. EnlmagnetisicrungsschalUing after 35 zuiandes, d. H. if the temperature-dependent wisdom 3, characterized in that (.let the two-stand is heated to its operating temperature, the secondary windings of the transformer (20) dio the voltage line between the temperature-dependent Rectifier noises (27, 30) for the original resistance and the resistance in the essential · The same voltages at both ends of the receiver are generated by equal operating voltages of the television (22) are connected. 40 niagnetisicrungsspulc results. This creates the tension gradient at the magnetization coil and consequently the residual current in the demagnetization coil degraded. In this way can / was the Resistrom can be reduced, however 45 current pulse pulses still occur if the tempo: uiur-dependent resistance and AC voltage applied to the Enlmagnctisierungsspule contains high frequency components. The process of learning. ·: Bctrill't an internalization / hole frequency components occur frequently in the second sound for the picture tube of an ear telephony receiver One branch of which is connected to parallel voltage sources by two series fed with a pure sinusoidal voltage, and because the secondary winding is loaded by the switching branch by the series connection of a learning element, especially diodes, which, if peralurable Resistors * with another 55 it is formed in the conductive and in the blocked state resistance and in whose diagonal a tensioned, abrupt change is switched in the secondary enlniagnctisierungsspule. cause voltage curve, so that high-frequency mc components are generated in an I .ochmasken-l'arbhildröhre. This is a particularly unlikely shadow mask and its mounting together pleasantly at home! ⁿ "crn with cold chasmil other metal parts of the tube the different sis. That is, in television receivers with isolating transformers, diagnostic influences, for example in the case of the mator - Risk of electric shock as little use as possible, exposed to such an undesirable measure, animalistic Enlmagnctisieriingsschalluii · gnelisieriing comes about, that the images on the secondary winding rope of the power transmission tube in the vicinity of magnetic fields how 65 t'orniaiors of the television receiver vi.r.
she /. B. in transport vehicles. Elevators and the like occur superimposed on these high-frequency components, or, during use, under the influence of a temporary disadvantageous voltage component, which comes from, for example, the earthly element. A harmonic wave is formed, which is caused by the