JPH0312484B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field of the Invention) The present invention relates to a radio wave interference prevention device for preventing interference due to excessive radio waves induced to the input side of target equipment such as an audio amplifier.

(Prior art and its problems) Audio amplifiers are generally used with a microphone connected to the input side via a long cable, and a speaker connected to the output side via a cable.

When an audio amplifier in such a state is placed near a medium wave or short wave band transmitting station, a high frequency voltage is induced in the cable due to the strong electric field radio waves from the transmitting station. This high frequency voltage is detected by the nonlinear characteristics on the input side of the audio amplifier, and the demodulated wave of the high frequency voltage is amplified and output from the speaker.

This kind of radio interference is noticeable near high-power transmitting stations such as international broadcasting stations, and the electric field strength is high.
When the voltage exceeds 90 dBμV/m, problems arise such as audio amplifiers becoming unusable without special measures. Possible audio amplifiers include karaoke sets, stereo sets, electronic musical instruments, mobile broadcasting, and even cable broadcasting, but these are generally purchased and used commercially, and in order to prevent radio wave interference, It is not appropriate to take measures inside the amplifier except in special cases.

Under the above circumstances, in order to prevent radio interference, it is common to take measures outside the set, and various radio interference prevention devices have been proposed.

However, all of the radio interference prevention devices that have been proposed so far are aimed at preventing induction from the power supply, and are not suitable for achieving the purpose of preventing the effects of high-frequency voltage induced in microphone cables and speaker cables. No such device has been proposed.

(Objective and Features of the Invention) In view of the current state of the prior art, the present invention
The purpose of the present invention is to provide a radio interference prevention device that is placed at the input terminal of an audio amplifier, has a high ability to block interference radio waves, and has broadband properties, and its characteristics are as follows:
An inductor is arranged on both the signal line and the ground line of the input terminal of the audio amplifier, and the inductor is shielded.

(Structure and operation of the invention) The present invention will be explained in detail below.

In determining the technical conditions of the present invention, the inventor determined that the JIS standard for the reception interference prevention device as shown in FIG.
Consideration was given to the standards. That is, an experimental study was conducted on the ability of the circuit configuration shown in FIG. 2 to block high frequency voltages on the input side of the audio amplifier.

First, a propagating high-frequency voltage induced in an input line such as a microphone cable has an asymmetric wave as a main component due to the distributed capacitance of the input line. Therefore, CB-A, CB-C, and F types of type C in FIG. 2, which are effective for asymmetric wave components, will be considered.

The C type is a type of filter that uses a capacitor as an element, but its effectiveness is low unless it is properly grounded (E). At the very least, using shear-searth would have the opposite effect as it would allow detours from the ground side. Therefore, although a separate ground is required, it is impossible to secure it at home, and it also imposes restrictions on how the device can be used.

On the other hand, the F type requires reliable grounding like the C type, although the series inductor has a blocking effect. In addition, commercially available F-type products are provided with a metal case, which is grounded. In this case, if the inductance of L is increased in order to increase the blocking effect, the (stray) path will flow into the metal case through the capacitance between the input of L and the metal case, and flow from the metal case to the main line via C. formation, and the blocking effect is reduced.

In the present invention, the inductor does not damage signals in the audio frequency band, has high impedance against unnecessary high-frequency voltages, and acts to shunt high-frequency voltages propagating through the input line to the ground. .

That is, in the radio wave interference device of the present invention, an input terminal and an output terminal are provided at both ends of a pair of audio signal lines, and the generation of direct induced voltage in the pair of audio signal lines due to interference radio waves is negligible. Two inductances with a small number of windings each using a core having a small size and a relatively high initial magnetic permeability μ ₀ to obtain broadband characteristics are inserted, and the two inductances are arranged so that the input terminal side is open. the shield plate is connected to one of the audio signal lines on the output terminal side, and the capacitance between the shield plate and the audio signal line on the input terminal side is This has the effect of reducing the leakage of high-frequency voltage generated on the input terminal side to the equipment to be prevented due to stray capacitance between the audio signal line on the input terminal side and the shield plate.

(Example) FIG. 1 shows an example of the present invention. In the figure,
1 is a signal line, 2 is a ground line, 3 is an inductor, and 4 is a shield plate.

In this example, the requirements for the inductor 3 are that it is small so that no direct induced voltage is generated in the inductor 3 by radio waves, and that it has a relatively high initial magnetic permeability μ ₀ in order to obtain broadband performance. It uses a core with fewer windings. In this embodiment, an inductor with an initial magnetic permeability μ ₀ of 850 (bead core FB-801 manufactured by Amidon, USA) of 0.2 mH is used, which is wound with nine turns. Of course, the higher the inductance of the inductor 3, the better. However, if the number of windings is increased in order to obtain high inductance, the capacitance between the windings will increase, and the blocking effect will be reduced due to stray through this capacitance. Furthermore, since a resonant circuit may be formed at a certain frequency, broadband properties are also lost. These points need to be taken into consideration.

Next, as shown in Figure 1a, the requirements for the shield plate 4 are that it should be formed and arranged so that the input side is open and the output side is closed, and that the capacitive coupling with the input line can be ignored. A sufficient distance should be maintained between the open side and the input line, and the grounding point should be on the output side (closed side) where unnecessary waves are sufficiently attenuated.

In order to reduce capacitive coupling with the input line,
It is also effective to provide a negative slope from the input side to the output side, as shown in FIG. 1b. Furthermore, it is best to arrange the shield plates 4 so as to surround the inductor 3, but depending on the electric field strength of unnecessary waves, one pair of the upper and lower or left and right shield plates may be sufficient.

With the configuration described above, it is possible to prevent direct induction of radio waves to the inductor 3 and prevent high frequency coupling between the input side and the output side, thereby achieving the desired purpose.

Next, the usage pattern of this embodiment will be described.

FIG. 3 shows an example in which this embodiment is arranged on the input and output sides of an audio amplifier. In the figure, 5
is the microphone, 6 is the microphone cable, 7
1 is an audio amplifier, 8 is a speaker cable, 9 is a speaker, and 10 is a radio wave interference prevention device of the present invention.

Figure a shows the progress of high frequency voltage mixing in a conventional form without using a radio interference prevention device, and Figure b shows the bypass of high frequency voltage by the radio interference prevention device of the present invention.

In Figure a, the high frequency voltages induced in the microphone cable 6 and the speaker cable 8 eventually mix into the input signal line of the audio amplifier 7, and undergo non-linear detection to become an interfering audio output. However, in Figure b, the high frequency voltage is blocked from advancing by the high impedance of the radio interference prevention device 10 and is shunted to ground. It has been confirmed that when a wire 11 having a length of 1/4 of the wavelength of the interference wave is connected to the ground wire as shown in FIG. b, the bypass effect increases.

Next, an example for commercializing the present invention as an adapter will be described.

In order to commercialize the present invention, it is required to have mechanical strength that can withstand handling and a structure that does not allow interference waves to enter. Therefore, in the embodiment shown in FIG. 4, the microphone jack plug 13,
14 is placed directly at the input/output of the radio interference prevention device 10, and in particular, the output side plug 14 is connected directly to the input jack of the audio amplifier to prevent interference waves from entering in between, and to connect the input/output plug jack. Non-metallic case 12 between 13 and 14
covered to ensure mechanical strength.

(Effects of the Invention) FIG. 5 shows the amount of attenuation in the 5MHz to 20MHz frequency band of the conventional radio interference prevention device and the radio interference prevention device according to the present invention by curves.

As is clear from the figure, the radio interference prevention device according to the present invention secures an attenuation amount of 26 dB to 35 dB, which is an improvement of 10 to 20 dB compared to the conventional type.

When the radio interference prevention device according to the present invention was applied to a karaoke set placed in an environment where the electric field strength of interference waves was 90 dBμV/m to 140 dBμV/m, no influence of interference waves was observed.

[Brief explanation of the drawing]

Fig. 1 is a circuit diagram showing an embodiment of the present invention, Fig. 2 is a schematic diagram showing a specific standard example of a conventional radio wave interference prevention device for power supply, and Fig. 3 a and b are a radio wave interference prevention device of the present invention. Connection configuration diagram to explain usage examples,
FIG. 4 is a schematic connection diagram showing a specific example of the configuration of the device of the present invention, and FIG. 5 is a characteristic diagram for explaining the effects of the present invention. 1... Signal line, 2... Ground wire, 3... Inductor, 4... Shield plate, 5... Microphone,
6...Microphone cable, 7...Audio amplifier, 8...Speaker cable, 9...Speaker,
10...Radio interference prevention device, 11...λ/4 wire,
12... Non-metallic case, 13, 14... Plug jack.

Claims (1)

[Claims] 1. An input terminal and an output terminal are provided at both ends of a pair of audio signal lines, and the shape is small enough to ignore the generation of direct induced voltage due to interfering radio waves in the pair of audio signal lines, and has broadband characteristics. Two inductances with few windings each using a core having a relatively high initial magnetic permeability μ ₀ are inserted, and a shield plate is arranged to surround the two inductances, and the shield plate has the output terminal side The shield plate on the closed side is directly connected to the ground side of the audio signal line on the output terminal side, and the open side is formed so that the input terminal side is the open side. A radio interference prevention device characterized in that the signal line is arranged at a distance from the input terminal side so that capacitive coupling therebetween is sufficiently small.