DE1131818B - Deflection coil system for cathode ray tubes, which is composed of deflection coils for vertical and horizontal deflection directions - Google Patents

Description

GERMAN

PATENT OFFICE

M 47403 VIIIc / 21g

REGISTRATION DATE: DECEMBER 14, 1960

NOTICE
THE REGISTRATION
AND ISSUE OF
EDITORIAL: JUNE 20, 1962

The invention relates to a deflection coil system for cathode ray tubes, which consists of deflection coils for vertical and horizontal deflection directions is composed, with a magnetizable Core and a plurality of superimposed wire winding layers thereon, the wire windings each layer are wound in the same spiral direction.

In the case of the vertical deflection coil of a cathode ray tube, the upper and lower layers of the Wire windings and a resonance circuit built up by self-capacities occurring between them. This resonance circuit is created by sawtooth-shaped voltage surges from the horizontal deflection coil vibrated, causing a detrimental deformation of the magnetic field lines of the vertical deflection coil has the consequence.

In order to remedy this disadvantage, it is known to make the magnetizable core with many layers To wrap wire turns in the same spiral direction. However, a deflection coil has known one Types, such as that described in German Patent 720 123, essentially one Right-angled cross-section with the same number of turns in every layer and uniform distribution of the turns in each position, so that no homogeneous magnetic deflection field is generated can and that with distributed windings of the horizontal deflection coil, the winding factor is very low and the goodness is diminished.

Another known type of deflection coil takes care of the disadvantages of fix the above-mentioned deflection coil, but the measure is too complicated and impractical to do to be found in common deflection coils use.

The above-mentioned disadvantages are essentially eliminated when used in accordance with the invention in the deflection coil for the vertical deflection, the wire windings of each layer are closest and in the middle part are wound against the opposite ends of the layer with a steadily increasing spacing. One Such a deflection coil is distinguished by the generation of a homogeneous magnetic deflection field.

Further details and advantages of the deflection coil system described emerge from the following Description of an exemplary embodiment.

In the drawing shows

1 shows a cross section through a conventional deflection coil,

2 and 3 corresponding circuit sketches of two conventional deflection coils,

Deflection coil system

for cathode ray tubes, consisting of deflection coils for vertical and horizontal
Deflection directions is composed

Applicant:

Matsushita Electric Industrial Co., Ltd.,
Osaka (Japan)

Representative: Dipl.-Ing. H. Leinweber, patent attorney, Munich 2, Rosental 7

Claimed priority:
Japan December 23, 1959 (No. 65 552)

Toshio Imanaka, Takatsuki-shi (Japan),
has been named as the inventor

Fig. 4 is a corresponding circuit diagram of a deflection coil according to the invention and

Figure 5 is a perspective view of a deflection coil according to the invention.

In Fig. 1, 1 denotes an oxide core around which a vertical deflection coil 2 with a large number of turns is wound. The coil 2 can also be wound in a distributed manner, as shown in FIG. Denoted at 4 and 5 are distributed horizontal deflection coils wound on the inner surface of the core 1. The horizontal and vertical coils are separated from one another by an insulating ring 6. As can be seen from Fig. 1, when the horizontal deflection coil is provided with a distributed winding according to cos Θ - cos ² Θ and when the vertical deflection coil with a rectangular cross-section has a high number of turns, a free space 7 is formed, which in relation to the cross-sectional area his goodness diminishes. Therefore, and in order to obtain a homogeneous magnetic deflection field, it is desirable to use a vertical deflection coil with distributed winding. However, it is not advantageous to accomplish the distributed winding only with the aid of a changed number of turns in each layer, as was customary up to now. In this connection, the excitation circuit can be viewed in terms of horizontal deflection shocks of the vertical deflection coil. If after

209 610/322

Fig. 2 the vertical deflection coil consists of two layers 11 and 12 with the same number of turns, which are wound in the same spiral direction, the magnetic deflection fields generated by them are additive, but the excitation circuit consists of a winding 11, a self-capacitance 13, with horizontal deflection shocks, a winding 12 and a self-capacitance 14, and the horizontal deflections generate voltages of the same magnitude but opposite directions in the windings 11 and 12. Therefore, the excitation circuit contains no self-induction, but only a capacitance and a resistance and thus does not generate any oscillation.

In Fig. 3, the vertical deflection coil consists of two layers 21 and 22 of distributed windings with different numbers of turns, which are wound in the same direction. Electric power for generating deflecting magnetic fields flows through respective parts 212, 211 and 213 of winding 21 to winding 22, and the deflecting magnetic fields generated by windings 21 and 22 are additive. When considering the excitation by horizontal deflection shocks, the winding 21, the self-capacitance 23, the winding 22 and the self-capacitance 24 establish a circuit very similar to that of FIG. 2, and no oscillation occurs. However, the winding part 212 and the self-capacitance 26, the winding part 213 and the self-capacitance 25 form an oscillating circuit that includes self-induction, capacitance and resistance. When the total inductance is on the order of 1H, oscillation of about 20OkH is generated, thereby causing disturbance of the images of the cathode ray tube.

As shown schematically in Fig. 4, two layers 31 and 32 of the same number of turns are wound in the same spiral direction, but the distribution of the turns is not consistently uniform, but the turns are closest at the central parts 32, 35, and towards the opposite ends the degree of winding steadily increases. With such an arrangement, because of the self-capacitances 33 and 34, the excitation by horizontal deflection impulses becomes the same as that of FIG. 2, with no oscillation occurring, but at the same time a homogeneous magnetic deflection field is obtained because the type of distribution is similar to that of FIG.

In FIG. 5, a deflection coil 41 is wound around a magnetizable core 40. The coil 41 contains 16 layers with 180 wire turns each. In the figure only the first layer is shown completely, and the wire leads to the starting point of the second winding layer.

The total number of turns of the coil 41 is 180 * 16 = 2880 turns. When using the Coil in a common cathode ray tube did not noticeably disturb the image due to horizontal Distraction shocks detected.

Claims (2)

PATENT CLAIMS: 1. Deflection coil system for cathode ray tubes, which is composed of deflection coils for vertical and horizontal deflection directions, with a magnetizable core and a plurality of superimposed wire winding layers thereon, the wire windings of each layer being wound in the same spiral direction, characterized in that the deflection coil for the vertical deflection the wire turns of each layer are most closely wound in the middle part and are wound against the opposite ends of the layer with a steadily increasing distance. 2. deflection system according to claim 1, characterized in that all layers have the same number of wire turns exhibit. For this purpose, 1 sheet of drawings © 209 610/322 6.62