DE2445003C3 - Television receivers with means for reducing the line interference radiation and methods for optimizing the means - Google Patents

Description

In a television receiver, it is known that the line deflection circuit causes interference radiation that leads to interference in neighboring radio receivers, especially those connected to the same power network can. This interference radiation occurs in particular on harmonics of the frequency of the return oscillation of approx. 40 kHz.

For this reason, state approval authorities have issued regulations for such devices which define maximum values for interference radiation that must not be exceeded.

It is known to reduce the interference radiation by shielding the parts causing the interference radiation. Such shields are structurally complex and often do not bring about a sufficiently strong reduction the interference radiation.

It is also known (DE-OS 21 63 772), a conductor between the line output stage and the line deflection coil to provide a screen and to connect another signal source to the screen, which essentially coincide with the line deflection voltage signals with opposite polarity as this generated. The shielding acts as a radiator that generates anti-phase interference radiation and thus the actual interference radiation is partially compensated.

However, this shielded power must be designed for a relatively high voltage, because on high voltage peaks of several kV occur on the connection line mentioned.

The interference radiation is particularly high if the deflection coil of the line output stage is not as in is conventionally fed symmetrically, but asymmetrically, so z. B with one end to the Line output stage and the other end to earth

ίο is connected such unbalanced circuits are predominantly used in transistor circuits. Previously, it was difficult to work with such circuits to keep the interfering radiation below the maximum permissible value with little effort.

The invention is based on the object with structurally simple means, in particular without the use of special shielded cables that interference radiation emanating from the line deflection circuit, in particular the influence of this

Radiation interference on the power grid to reduce.

This object is achieved by the invention described in claim 1. A method for Determination of the optimal position of the antenna according to claim 1 is specified in claim 8. Advantage

2s th embodiments of the invention are in the rest Subclaims indicated.

The invention is based on the knowledge that with an antenna the shape of a simple straight or bent wire, which is fed with a voltage in phase opposition to the line deflection voltage, the Can reduce the effect of the interfering radiation on the power grid surprisingly easily and effectively. The optimal dimensions and alignment of the antenna can be determined empirically by changing of these two parameters the interference radiation occurring in the power grid is measured.

The aforementioned DE-OS 21 63 772 already teaches that the radiation from the shielding of the line to the deflection coil can compensate for the radiation of the unshielded ends of this line and the components located at the input and output of this line. However, this solution makes use of an existing shield in every case and is thus structurally linked to the existing deflection circuit, namely to the position of the line mentioned. A suggestion not only to change the length of the shielding acting as a radiator, but to omit it entirely and use a separate antenna as the radiator, is not to be found there. All the less there is a suggestion to apply this own antenna with the known anti-phase compensation signal and - in contrast to the position prescribed by DE-OS 21 63 772 - its spatial position in the device housing with regard to an optimal effect and taking into account manufacturing issues such as B. easier and faster attachment to choose freely.
The invention is explained using the drawing using an exemplary embodiment. In it shows
F i g. 1 shows a basic diagram of the invention,
F i g. 2.3 different designs of the antenna.
Fi g. 1 shows a line oscillator and amplifier 1, a line output stage transistor 2, a line transformer

C) 5 mator 3 with a primary winding 4 and one Additional winding 5, a coupling capacitor 6, a deflection unit 7 and one in a housing 8 arranged picture tube 9. The line output stage supplies

the line deflection coil contained in the deflection unit 7 with a line deflection voltage 10. The with its The deflection coil grounded at the other end is thus fed asymmetrically Radiation interference, e.g. B. on the 5th harmonic (200 kHz) of the frequency of the return oscillation (approx. 40 kHz). This interference radiation acts in particular on the power grid feeding the receiver and can thereby interfere with other radio receivers connected to the mains.

Between a support point 11 on the deflection unit 7 and a support point 12 on the inside of the upper wall of the housing 8 is an antenna acting as an antenna straight wire 13 is provided. This wire is used by the auxiliary winding 5 with a line deflection voltage 10 is fed at the same time, but in phase opposition, voltage 14 and thus causes a line deflection voltage antiphase interference radiation which prevents the interference radiation emanating from the voltage 10 Support point 11 is only attached to the deflection unit, but has no electrical connection to it the deflection coil itself The antenna formed by the wire 13 is sensitive to the disturbing harmonics Frequency of the return oscillation z. 13. The wire 13 is tuned to the 5th harmonic of approx. 200 kHz aligned through experiments so that those in the power grid remaining interfering radiation, which can be determined by measurement, becomes a minimum.

In Fig. 2, the wire 13 extends obliquely from the upper edge of the deflection unit 7 to the upper inside the wall of the housing 8. The wire is in turn connected at the lower end to the additional winding 5 and runs out freely at the top.

In Fig. 3 the wire 13 is angled and on two Points 12.15 hung on the wall of the housing 8 This solution is useful when the wire because of its length cannot be stretched straight out.

The optimal effect of the antenna reducing the interference radiation can be achieved in particular by three Achieve variation possibilities, namely through the amplitude of the voltage 14, through the vote, d. H. the length and orientation of the antenna. The optimum values for this are preferably empirical determined by measuring the interference radiation in the power grid. As an advantageous value for the amplitude of the Voltage 14 has resulted in a value which corresponds approximately to the amplitude of the voltage 10 At practically In the examples tested, the wire was 24 and 32 cm long.

1 sheet of drawings

Claims (8)

Patent claims: 1. Television receiver in which a deflection voltage is used to reduce line interference Antiphase voltage to a device used to compensate for the interference radiation inside the device housing firmly arranged strahier is applied, characterized in that the radiator is designed as an antenna (13) whose position can be selected is 2. Television receiver according to claim 1, characterized in that the antenna (13) on disruptive Harmonics (200 kHz) are matched to the frequency of the return oscillation (40 kHz) 3. Television receiver according to claim 2, characterized in that the antenna (13) on the 5th harmonic of the frequency (40 kHz) of the return oscillation is tuned 4. Television receiver according to claim 1, characterized in that the antenna is a straight wire (13) is formed 5. Television receiver according to claim 4, characterized in that the wire (13) extends from the Deflection unit (7) extends to the inside of the housing wall (8) 6. Television receiver according to claim 4, characterized in that the wire (13) extends from the Deflection unit (7) extends up to the housing wall (8) and then along the housing wall (8) runs 7. Television receiver according to claim 4, characterized in that the wire (13) has a length of approx. 20-40 cm 8. A method for determining the optimal position of the antenna according to claim 1, characterized in that that the position of the antenna (13) in the housing is experimentally changed until the same time Line interference radiation measured at the mains terminals has reached a minimum.