RU2084081C1 - Electrodynamic microphone - Google Patents

Abstract

FIELD: audio signal reception. SUBSTANCE: microphone has case, diaphragm built up of central, corrugated, and peripheral parts, magnetic circuit, sound coil wound on side part of diaphragm and connected to amplifier input through audio-frequency filter; amplifier output is connected to compensating coil winding fixed to case. Case accommodates compensating magnet fixed to it at bottom through spring and having insulating packing. EFFECT: improved design. 3 cl, 2 dwg

Description

 The invention relates to acoustics, and in particular to designs of electrodynamic microphones.

 Known designs of electrodynamic microphones [1] containing a housing in which a diaphragm having a central and corrugated parts, an upper and lower flange, a magnetic system consisting of a permanent magnet, a pole tip and a magnetic circuit, and a sound inductor located in the air gap between top flange and pole piece.

 In typical designs of electrodynamic microphones, the corrugated part of the diaphragm is located above the upper flange.

 The disadvantage of this design is that when the diaphragm of the microphone is exposed to increased acoustic pressure outside the nominal operating frequency range, namely, ultrasonic acoustic waves, a decrease in the upper value of the dynamic range can occur, which will significantly impair its performance in the nominal frequency range.

 A prototype of the invention is an electrodynamic microphone [2] comprising a housing, a diaphragm having a central, corrugated and peripheral parts, a magnetic circuit having a permanent magnet, a pole tip and a magnetic circuit, a voice coil located in the air gap between the pole tip and the upper flange, the voice coil attached by the upper base to the central part of the diaphragm, and the lower base to its corrugated part located above the upper flange.

 The disadvantage of this microphone is the lowering of the upper boundary of its dynamic range when exposed to its diaphragm of low-frequency noise lying outside the working frequency range of the microphone.

 The technical result of using the invention is to increase the noise resistance of an electrodynamic microphone without changing its dynamic range when a diaphragm of a noise source with a low frequency is exposed outside the nominal operating frequency range of the microphone.

 This result is achieved due to the fact that a feedback circuit is additionally introduced into the electrodynamic microphone, through which an audio signal with a frequency below the nominal range acts through the mechanical system on the diaphragm from the back side in antiphase to the acoustic pressure acting on the front side.

 In FIG. 1 presents the proposed microphone; in FIG. 2 is the same, section AA in FIG. one.

 In the housing 1 there is a magnetic system consisting of a permanent magnet 2 and a magnetic circuit 3 and a pole piece 4 rigidly connected to it. The magnetic circuit is fixed in the housing using the upper flange 5 and the lower flange 6 fastened to the housing. The housing has front holes 7 and side holes 8. At the junction of the upper flange and the magnetic circuit there is a ring 9, which serves to fix the diaphragm containing the upper part 10, the corrugated part 11, the peripheral part 12, and also the side part 13, which is the voice coil frame 14 located in the air gap 15 between the upper flange and the pole piece. The winding of the voice coil is electrically connected to a low-pass filter 16, the output of which is connected to the input of the amplifier 17. The output of the amplifier is connected to the windings of the compensating coil 18 wound on the frame 19, structurally connected to the housing. Inside the frame is a permanent compensating magnet 20 connected to the housing by a spring 21. A dielectric nozzle 22 with a holder 23 is inserted on the upper pole of the magnet through holes 24 in this part of the magnetic circuit. A cylindrical ring 25 having mechanical contact with the corrugated part of the diaphragm is mounted on the end parts of the holders.

 The microphone operates as follows.

 When a noise source with a radiation frequency is found, a low-frequency sound field acting on the acoustic part of the diaphragm located below the nominal operating frequency range of the electrodynamic microphone on the acoustic axis acts. Thus in the winding of the voice coil 14 there is an electric current of low frequency outside the nominal range of operating frequencies. This current is supplied to the low-pass filter 16, and from its output to the input of the amplifier 17. From the output of the amplifier 17, an alternating electric current is supplied to the winding of the compensating coil 18, creating an alternating magnetic field inside its frame that acts on the compensating magnet 20 having a certain range of movement due to the fact that it is connected to the housing not rigidly, but by means of a spring 21. If the magnetic lines of force of the magnets 2 and 20 coincide, the windings of the coils 14 and 18 must be turned on when the amplifier 17 does not invert the signal coil 14 or according to, if the amplifier 17 inverts the signal of the voice coil 14. Moving up, the compensating magnet moves up the holders 23, which, passing through the hole 24, move up the cylindrical ring 25, which produces pressure on the corrugated part of the diaphragm in antiphase acoustic pressure on the Central part aperture 10.

Claims (3)

 1. An electrodynamic microphone comprising a housing, a diaphragm consisting of a central, corrugated and peripheral parts and secured with a ring at the junction of the upper flange and the magnetic circuit, a magnetic circuit consisting of a permanent magnet, a pole piece and a magnetic circuit rigidly fixed in the housing by the upper and lower flanges, a voice coil wound on the side of the diaphragm with a winding located in the air gap between the upper flange and the pole piece, characterized in that the output of the voice cat the shki is connected to the input of the low-pass filter, and the output of the low-pass filter is connected to the input of the amplifier, the output of which is connected to the winding of the compensating coil, rigidly connected to the housing, inside of which a compensating magnet is coaxially located, attached to the housing through the spring through the bottom and containing in the upper part dielectric nozzle fastening the holders, providing through the holes in the bottom of the magnetic circuit the contact of the cylindrical ring with the corrugated part of the diaphragm.  2. The microphone according to claim 1, characterized in that the compensating magnet and the permanent magnet of the magnetic system are installed so that the magnetic lines of force of the compensating magnet are aligned with the magnetic lines of force of the permanent magnet of the magnetic circuit.  3. The microphone according to claims 1 and 2, characterized in that the winding of the compensating coil is turned on against the winding of the voice coil with a non-inverting amplifier and according to the winding of the voice coil with an inverting amplifier.

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