DE1916104C - Device for correcting pillow distortions - Google Patents

Description

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The invention relates to a device for designing the invention are two permanent magnets Correction of pillow distortions in a remote control provided.

Vehempfänger od., Like. In which one by means of a

Permanent magnet system controllable Transduktoran- disadvantages of the prior art discussed in more detail.

Order affects the deflection currents. 5 As is known, the magnetic properties

As is well known, a pinch distortion of a ferrite core is strongly influenced by the temperature that the vertical amplitude of a raster flows because the curve point is lower than that of the center of which around AV is too small 'cf. Fig, 1). As is well known, such a distortion changes as a result of the μ-value of the magnetic circuit with the temperature, corrected by the fact that the Vcrtikalablenkwinkel in the io this change in magnitude of the μ-value furthermore in the middle part of the horizontal scan depends maximally on the magnetic flux density. The comparison of power. In detail, the correction can be carried out in the transductor * according to the invention with the transductor way that a parahol current of the known type takes place with regard to the temperature-horizontal scanning period essentially linear properties in the dynamic state. While the changes according to the curve of the scan line, so that the direction of the bias magnetic field through which the deflection current is kept constant during the first half of the verti device, the cal scan is increased in the negative direction, the direction of the magnetic flux alternating in positive it changes during the second half of the vertical and negative direction, which is enlarged in the core by the scanning in the positive direction, such as the vertical deflection current flowing through the coil, as shown in FIG. 2 is shown. So that one becomes such an ao. Thus, when the corrective waveform is obtained by the magnet, different pretensioning flux and that by the vertical dent: circuits have already been proposed which use a parabo-deflection current in the coil, opposing current, which have directions set vertically, so the flux density is very deflection waveform modulated, or else it is small, in the opposite case it is large.
Circuits proposed which use a diode 25 A correction voltage (V ₁ ) for the pillow-type push-pull modiilator. drawing is determined by the difference between the

Furthermore, it is already known to use correction circuits, inductances (or magnetic permeabilities) which work with magnetic amplifiers, which determine the horizontal coils in both cases, as shown, for example, in FIG. 3 and 4 as well as in the German Auslegeschrift 1 257 827, which in turn describes the temperature properties. 30 are correct, and the mentioned correction-In these known circuits magnetic voltage is less influenced by temperature changes in the case of amplifiers (transducers) with closed dimensions of an open magnetic circuit, although more than in a closed circuit. In particular, there are disadvantages, especially with regard to the temperature, of the following. If one uses an open characteristic, when balancing the correction voltage 35 magnetic circuit, wherein a core and magnet are arranged according to between the two magnetic circuits and according to the invention, the magnet of the mechanical vibration characteristics will occur. core in a state near the saturation zone These disadvantages are operated below for clarification purposes, as shown in FIG. 11 (bc) . With chung also explained in more detail with reference to figures. the known arrangements where a closed

The invention is based on the object, finds the 40 magnetic circuit use is the magnetic-disadvantages avoid known correcting devices to comparable core in a relatively unsaturated zone and focus particularly such Korrekturvor- operated at providing unless direction a very strong magnet which is used at a good temperature. Since the inductance of a coil is not determined by mechanical oscillation t-dB / dH properties, it is easy to see that tendencies and a slight adjustment 45 allow the change in inductance due to temperature. is maximum near the zone h in FIG. 11.

To achieve this object of the invention is provided according to the case of a transducer with a closed magnet: a first and a second circuit operating in the region from, is when the in each case by an open solid coupling to one, two produced the magnet magnetic flux and the magnetic core, which is wound by magnetic circles forming magnetic circles, is opposed to the vertical coil and the horizontal coil that flows in the vertical coil of the transducer. have the inductance change due to temperature intersections, and where the vertical and rise are relatively small (cf. 1-2 in the horizontal styles each with each other in series 55 Fig. 11 and 12), while when the two are connected that the through the Horizontal coils flows in the same directions the change in the magnetic fluxes induced in the vertical coils in the two coil systems in opposite directions due to the rise in temperature is relatively large (see Fig. 3-4 in Fig. II and 12).

gene run and where furthermore the permanent- As a result, the correction voltage strives to

magnet system with the magnet cores of the 60 with a temperature change from Tl to Tl (\)

Coil system is related to that while increasing. The size of the correction stress at

the first and second half of the vertical deflection T \ is proportional to the difference between the in-

Due to the different directional ductivity of the two coil systems (or A in

Currents generated magnetic fluxes in opposite directions becin- Fig. 12); furthermore, the stress at Tl is proportional

flows pastures. 65 tiona! to B. Finally, the relationship applies

According to a preferred embodiment of the invention, A <B.

provision is made for the permanent system to be

is adjustable. (According to a further preferred embodiment who works in the area bc - if the through

I 916 104

3 4

to compensate the magnetic flux generated by the magnet and that of Irish connections, so that then,

those flowing in the vertical coil of the tran.iductor, if only the number of coil turns around each

Vertical current generated magnetic flux is set opposite open magnetic core, the compensation

Directions - the change in inductance due to the full-

Temperature rise relatively large (cf., 3-4 5 will come, with the upper and lower linden

in! · 'i g. 11 and 12), where, on the other hand, if they are equally correctable,

both rivers have the same direction, which further advantages and details of the invention

Changes in the temperature rise are given in the description of the execution

is klcin (see 5-6 in Figs. II and 12). examples on the basis of the drawing: in the drawing

As a result, the correction voltage tends to show io

with a relief of Tcmperntur from 7Ί to 7'2 (/ f) Fig. I and 2 representations to explain the

decrease, in particular the correction span pillow distortion,

nungswert at the temperatures Ti and 7'2 propor- F i g. 3 and 4 representations of a corrective deer

tional to C or D in Fig. 12, Furthermore, hang and correction device applies. the explanation of the

the relationship OD. 15 device according to the invention are useful.

On the other hand, since the inductance (L) of a F i g. 5 shows the principle of FIG

Coil generally designed pillow correction devices as the temperature of the invention rises.

decreases, the horizontal input current (which hung in one,

Transductor flowing horizontal current) strives with F i g. 6 and 7 side views of two un-

to increase the temperature rise, both ao different trained according to the invention

for the open management examples formed according to the invention,

Magnetic circuit, as well as for the well-known Gesehlos- · F i g. 8 to 13 to explain how the magnetic circuit works. As a result, the correction voltage (V ₁ ) serving the device according to the invention increases with increasing temperature () ·) at positions.

(see Fig. 13). a ₅ The device shown in FIGS. 1 to 4 according to the invention compensates for the increase in the correction of pincushion distortions of the correction voltage (γ) by the increase in the horizontal input 1 257 827 accompanying the temperature increase. Therefore, a detailed description of this device, the drop in the correction voltage (ff), is required here, not due to the change in inductance of the horizontal 30, while in the following operation and coil of the transducer is generated, which depends on the effect of the device according to the invention mentioned above Temperature rise is accompanied. In the hand of Fig. 5 will be described in detail.
In contrast to this, in the case of the closed Ma- The pillow magnet core of the El type of the correction voltage correction device designed according to the invention has two magnetic cores 1 and 2 increase (>') the increase in correction voltage (\), 35, which is made of a ferrite or. Like. exist, wherein the by the change in inductance of the horizontal each core is H-shaped in cross section and a coil of the transducer is generated, which has the easily magnetically saturable winding part, accompanied by the above-mentioned temperature rise. On the magnetic cores 1 and 2, a first or a second coil system I or II is provided with regard to mechanical vibrations; this should be pointed out that tightly coupled "vertical" magnetic core dc ^r El-type and a spacer be- "horizontal" coils L _1, L ₁ and L ₁ in a closed coil systems 40 included ', _L:,'. Furthermore see Ε-core and the I-core sits so that the permanent magnets 3 and 4 are adjustable adjacent ^ // - properties of the transducer a good contact to the end faces of the magnetic core 1 and the mastieg as well as the linearity of the correction voltage gnetkernes 2 produce a η in the opposite relationship. However, such a transductor 45 is arranged.

mechanically oscillatable, namely with the coils L ₁ , L ₁ ', L ₁ and L _{: i} ' are mutually vertical and horizontal frequencies. The invention in such a way in series that the direction of the magnetic flux, object does not have such disadvantages. that in the »vertical coil through the» horizontal line is advantageous in the subject matter of the invention, coil is induced in one coil system, in contrast to the fact that the magnetic bias is simply set by 50 to that in the other coil system. The rotation of a magnet can be adjusted, as there is a series connection between the individual elements shown in the exemplary embodiments. In these 'horizontal coils L ₃ and L ₁ ' and between the ways, an adjustment can be carried out more easily 'vertical coils L ₁ and L 1' in such a way that the direction can be changed than by moving a bar magnet. of the magnetism induced in the "vertical coil L ₁ by the" horizontal "- finally, the structural difference 55 coil L ₃ in the first coil system I between the transducers of the known correction fluxes opposite to the direction of the magnet door devices and the device according to the invention. Flusscs runs, which in the "VertikaU-coil /.," indicated by Hing. While in the known trans- the horizontal coil L ₃ 'in the second coil inductor, the equilibrium between the two system II is induced. Furthermore, the tin of the first magnetic circuits is strongly influenced by the state of the connection 60 coil system I (or the second coil system). arranges that the direction of the magnetic flux ^ ₁ (or duktor provided in which a magnet next to Φ, '), which is through a through the »vertical coil L _{1 of} the end face of an open magnetic core, where (or L ₁ ') des The first coil system I (or the second, the right and left magnetic circuits separately from the coil system) is generated, formed identically and magnetically independent of each other (or opposite to) the direction of the magnet, so that the direction of the magnet in the vertical coil of the Trar.r.ductors flusses </ \, (or <!>"') , the horizontal component induced by the permanent magnet emanates from external elec- 3 (oiler 4). F sharp it is clear that when reversed

the polarity of the vertical deflection current is the previous one Relationship completely reversed.

The operation of the device is described below. If no vertical deflection current flows, so cancel each other one in the "Vcrlikal" - Spulc / induced voltage -. This voltage is induced by a magnetic flux resulting from a current flowing through the "horizontal coil L ₁ Hoiizontalablenkstrom - and one in the 'Vertical coil /.,' Induced voltage, the latter voltage being generated by magnetic flux resulting from a horizontal deflection current flowing through the '' horizontal coil L ₁ '; as a result of this cancellation of the two voltages, no correction is made for the vertical deflection during the central part of the horizontal scan. When the vertical deflection current is maximum during the first half of vertical scan, the \ is opposite on the "Vertikaln-Spulc L _x stemming magnetic </>, and the magnetic flux _Φ ο by the permanent magnet 3, while the \ on the" vertical "- Coil /., 'Originating magnetic flux Φ,' and the magnetic flux 0 ,, 'are rectified by the permanent magnet 4, so that the magnetic core 2 is magnetically saturated in the second coil system. (During the last half of the vertical scan, the magnetic core 1 of the first coil system is saturated in the same way.) The inductance of the »horizontal coil /. _; 'of the second coil system is thus reduced so that the magnetic flux coming from there is correspondingly reduced: the inductance of the horizontal coil L _{3 of} the first coil system is increased during this, so that the magnetic flux coming from there is correspondingly increased As a result, a horizontal deflection current corresponding to the difference Φ _Ά - Φ _Λ ' between the magnetic fluxes coming from the »horizontal coils is superimposed on the current flowing through the series of» vertical coils,

Such an effect is shown in FIG. 8 and 9 can be seen. In Fig. 8 shows the case where the originating from the permanent magnet magnetic same size as the maximum "IuIJ magnetic 1- the corresponding" vertical coils. In V i g. 9 is the case illustrated where the light coming from the permanent magnet magnetic FIuB Φο is greater than the maximum magnetic flux 0, max from the corresponding vertical coils. In this case the correction value is smaller than in the case of Fig. 8. In other words, the greater the magnetic flux coming from the magnet Fig. 10 shows how the magnetic flux of each permanent magnet becomes different for each coil system. In this case, the amount of correction is different for the first and last half of the scan That there is an imbalance in the upper and lower distortions between the first and last half of the llori / ontalabtasUing, it is possible to detect such Correcting unbalanced pillow designs individually and independently, simply by adjusting one of the magnets.

In the I i g. h and 7 are two geniiiH iln I Hindun; Hn ilci in I i i- ^? For the device provided, first and second coil systems I and II are placed next to one another in a fastening element provided on a base plate 5; permanent magnets 3 and 4 each formed with a setting recess 7 are rotatably supported with respect to the magnetic cores I and 2 by non-magnetic bands 9 which have bent parts that engage with the end faces of the magnets and other non-magnetic bands 12

ίο set which with leg parts 11 in recesses 10 are used, which are formed in the Haltungsglicd 6 are.

In the case of the FIG. 7 are the magnetic cores for the first and second Coil system made of ferrite as if two separate cores were backed up Backs are arranged to each other, with an axially relatively thick central flange 13 is provided through what interference between the andit opposite

Magnets 3 and 4 arranged on the sides should be avoided. The other parts are essentially the same as in FIG. 6 and are therefore given the same reference numerals.
In an experiment carried out, H-promotional

moderate cores manufactured by Taiyo Yudeiisha as model D.-DBN were used; these cores have a diameter of the opposite end faces of 14 mm, the The diameter of the winding part is 6 mm

The thickness of the left side surface is 1.5 mm, that of the right side surface 2.5 mm; the length of the winding piece is 2.5 mm, with 70 turns of the »horizontal coils (0.35 diameter) [with a electrical resistance of 0.71 Ohm] and 70 winding

ungen »VertikaN-Spulen (0.26) [with an electrical Resistance of 0.92 ohms] were wound. A pulse voltage of 100 Vpp (peak to Tip) from the third winding of a flyback transformer to the »horizontal coils,

and a correction voltage of a maximum of 120 Vpp (peak to peak) and a minimum of -.5 Vpp (Spuzc to peak) was achieved. I _n the F g in i. 7 illustrated embodiment, a pulse voltage of 50 Vpp (peak to peak) was applied to the hori-

zontalablnnkspule applied, and thus obtained a correction voltage of maximum 100 Vpp (peak

m «5 ^P ? ? ^C) "..? ^{Nd, mmimaI 'V} W ^(S P ^{itzc z"} peak) Ge-Ä η ^{b d} 5Y ^ora "g ^e HS ™ en embodiments, the Erhndung can deflection correction Zf ^{Fuei; Black} - ^{Wci (1} -l- "ernsehem _P catcher as Ma-Kn '" of ^the "stipulated Vo, direction to be

Claims (3)

Patent claims: 1. Device _m correcting Kissenvcr- ".Khnungcn in a television receiver finger od. The like., Ίν learning Γ" Ι ^{"0 means eilies} ^ rmanentmagnet-IcnLTpHm · ^nre J ^ransd ^ t" rnnordnung affects the Abknkströme, characterized mrJser K Li '^ ^l " ^{ld Ci} "' ^{Weites <iweils: ine} before KriS ^P T. ⁸ T ^einCn · ^{7wcj ofTcnc mn} ß ^llcti - Ve \\ Λ η f, i ^{lldcndt: n} ., /., ■> and H.Mi / ontalspule (/ ..,. L ₁ ') i coil system (I. ||), _{where the wick} . Of the same magnetic core (1. 2) works ■ "« ■ • n «/ u siitienden cross-sectional alliichi-n» ■ ""'I «ohi-i the vertical and ll.iri / .tn- r »ι c Ό 1 W valley coils are connected in series with one another in such a way that the magnetic fluxes induced by the horizontal coils (L ₃ , L ₃ ') in the vertical _{coils (L 1} , L ₁ ') run in opposite directions in the two coil systems, and the permanent magnet system ( 3.4) is related to the magnetic cores (1, 2) of the coil system in such a way that the during the first and second half of the vertical deflection by ι r \ /, the different direction possessing currents generated magnetic fluxes influenced in opposite directions will. 2. Apparatus according to claim 1, characterized in that the permanent magnet system (3, 4) is adjustable. 3. Apparatus according to claim 1 and / or 2. characterized in that two separate permanent magnets (3, 4) are provided. For this purpose 2 sheets of drawings 109 634,