FR2504299A1 - Electromagnet transducer capsule adjustment instrument for telephone - uses artificial ear to receive acoustic signal from transducer in magnetic field from solenoid - Google Patents

Abstract

The output of a transformer (9) connected to the mains supply is coupled to a winding assembly (2) in which an electromagnetic transducer (3) is mounted. A thyristor (12) triggered from a control circuit (15) provides a rectified current for the winding. A changeover switch (13) allows the current flow to be inverted. The current amplitude is limited by a resistor (R) to ensure the maximum value of magnetic field is less than the coercive field of the magnetic material in the transducer. In operation, the transducer is driven by a signal generator (5) and the acoustic output from the transducer is received by an adjacent artificial ear (6). The ear output is amplified (7) to drive an indicator (8). A microprocessor coupled to this circuit permits automatic adjustment of transducers to be effected.

Description

Method and device for adjusting an electromagnetic transducer capsule
The invention relates to a method and a device for adjusting an electromagnetic transducer capsule constituted by a permanent magnet motor, a movable assembly integral with a membrane, a case and a cover. Such a capsule operates both in transmission and in reception without prior modification of its characteristics; it can therefore be used either as a microphone or as a headset.

 Adjusting the permanent magnet capsules is always difficult and time consuming. For reasons of handling and especially of maintaining their characteristics, the permanent magnets are mounted demagnetized; magnetization is carried out when the engine is mounted, without play, in the case. The moving assembly secured to the membrane must be mechanically centered with respect to the magnet; in certain types of capsules the centering is obtained by mechanical adjustments and it is necessary to measure the effectiveness of the capsule after each adjustment. In other types of capsules the centering of the membrane is ensured by the shoemaker, the cover coming to hold the membrane in place in other types of capsules the membrane is centered and fixed on the cover which fits precisely in the shoemaker thus ensuring the centering of the moving assembly.

 In all cases, the magnetic induction must be adjusted in the air gap of the motor, air gap in which 11 mobile equipment takes place; the measurement of this induction cannot be done directly, owing to the requirement of the air gap, but only by a measurement of the leakage induction, which is not precise; the dispersion range in the results for measuring the effectiveness of the capsules is, under these conditions, of the order of 2.5 decibels. It should also be noted that the magnetization, control and adjustment operations are separate operations for each of the factors of the efficiency of a capsule, which, in addition to the measurement inaccuracy which results therefrom, are relatively long and cause handling of each capsule. Taking into account the range of dispersion, it is difficult to keep a "template" giving the maximum and minimum characteristics between which the capsules must be located.

 The object of the present invention is to simplify the magnetization, adjustment and control operations of the capsules, and to reduce the cost thereof by adjusting the adjustment at once, assembly assembled for all of a sudden canceling the effect. of all the dispersions that combine.

 The subject of the invention is a method of adjusting an electromagnetic transducer capsule comprising a permanent magnet motor made of remanent magnetic material and a coil integral with a membrane, characterized in that a capsule assembled with the interior of a solenoid, which is carried out as follows: magnetizing to saturation the remanent magnetic material of the capsule, applying to the remanent magnetic material a pulsed demagnetizing field of amplitude less than the coercive field of the magnetic material, performs a measurement of the effectiveness of the capsule by applying an electrical signal to it in a determined frequency range and by measuring an acoustic signal emitted by the capsule, then repeating the demagnetization and measurement operations until the measurement of the acoustic signal falls within a predetermined measurement range, the demagnetizing field increasing from one operation to another.

 The invention also relates to a device for adjusting a capsule implementing the method, and characterized in that it comprises a coil, in the form of a solenoid powered by a power source delivering current pulses, an artificial ear inside the coil, a frequency generator, an amplifier and a measuring device, the capsule to be adjusted being placed above the artificial ear, inside the coil.

 The invention will be described with the aid of a nonlimiting exemplary embodiment illustrated by the appended figures in which - FIG. 1 is a basic electrical diagram of an adjustment device of the invention, - FIG. 2 represents in partial section and in elevation a part of the apparatus of FIG. 1.

 The method of adjusting a capsule of an electromechanical transducer of the invention consists in carrying out all the magnetization operations of the magnet at saturation, then of adjustment and measurement, on a capsule assembled and placed inside. of a solenoid. After saturation of the magnet, it is subjected to a demagnetizing field, for a short time, and a measurement of the effectiveness of the capsule is carried out; if the latter is not good, a demagnetizing field is again applied, of a value greater than that of the preceding demagnetizing field, and a measurement of the effectiveness of the capsule is carried out. The demagnetization and efficiency measurement operations are repeated until the capsule is good, the demagnetizing field increasing from one operation to another.

 The magnetic saturation of the magnet is obtained by applying a magnetic field for a short time.

 The demagnetization is obtained by application, for a short time, of a magnetic field opposite to the magnetic field of saturation, and of amplitude lower than the value of the coercive field characteristic of the material of the magnet. If after a first demagnetization the capsule is not declared good, a second demagnetization is carried out by applying for a short time a magnetic field of amplitude greater than that of the magnetic field applied during the first demagnetization. Likewise during successive demagnetizations, if they are necessary for the capsule to be deemed good, the magnetic field applied increases from one demagnetization to the next, while remaining below the coercive field. In this way, magnetic stabilization of the magnet, while having after each demagnatization a decreasing magnetic field in the air gap of the motor of the capsule this therefore allows the adjustment of the capsule from a maximum value of the magnetic field in the air gap of the motor.

 FIG. 1 is an electrical schematic diagram of a device for adjusting a capsule, for implementing the method of the invention. In this figure a power source 1 is supplied by the alternating power network; a coil 2 is supplied by the power source 1; a capsule 3, to be adjusted, is subjected to the magnetic field created by the coil 2, and is connected, through a switch 4, to a frequency generator 5. An artificial ear 6 is placed near the capsule 3; it is of the condenser microphone type and is supplied with direct current at a voltage V.

 The output of the artificial ear 6 is connected to the input of an amplifier 7, the output of which is connected to a measuring device 8.

 The power source 1 is of any known type, the magnetization of a magnet being an operation well known to those skilled in the art; it essentially comprises a transformer 9, the primary winding 10 of which is supplied by the alternating power network; the secondary winding 11 is connected to an inverter 13, through an adjustable resistor R and a unidirectional device 12, with controlled conduction, such as a thyristor for example; the thyristor 12 is controlled by a control circuit 14, which includes a switch 15, for example.

 The coil 2 is a solenoid inside which are placed the capsule 3 and the artificial ear 6 which has no magnetic part. The frequency generator 5 is for example a white noise generator which delivers a continuous spectrum of weighted frequencies; it preferably conforms to the standards of the Post and Telecommunications Administration.

 The artificial ear 6 and the amplifier 7 preferably each have a linear bandwidth up to at least 20,000 Hertz. For reasons of impedance the amplifier 7 is placed close to the artificial ear.

 The power source 1 being supplied by the AC network and a capsule 3 being placed in the coil 2, the inverter 13 is put in the position which corresponds to the magnetization of the magnet of the capsule, the adjustable resistance R being at its minimum value. The switch 15 is pressed, which makes the thyristor 12 passing during alternating alternating current, that is 10 milliseconds for an alternating current of frequency 50 Hz.

 The coil 2 is then traversed by an amplitude current of the order of 800 to 1000 amperes. The position of the inverter 13 is then changed to reverse the direction of the current in the coil 2, and the adjustable resistance R is adjusted in order to limit the amplitude of the current. The switch 15 is pressed, which makes the thyristor 12 passing during an alternation, the amplitude of the current being limited by the resistance R so that the maximum value of the field in the coil 2 is less than the coercive field of the material of the magnet of the capsule 3.

 After each demagnetization, an efficiency measurement of the capsule 3 is carried out; for this, the capsule is connected to the frequency generator 5 by closing the switch 4.

The acoustic emission of the capsule is received by the artificial ear 6 which delivers a signal, which after amplification by the amplifier 7 is applied to the measuring device 8 which is, for example, a logarithmic voltmeter. If the capsule is not good, switch 4 is opened and a new demagnetization of the magnet of the capsule is followed, followed by a new measure of effectiveness, until the capsule is declared good, or possibly declared bad if after a series of demagnetizations, a correct value could not be obtained on the measuring device 8.

 The measuring device 8 must of course be previously calibrated; for this, a capsule is used on which an efficiency measurement has been carried out by the usual methods, which makes it possible to locate it in relation to a "template" corresponding to the type of capsule to be adjusted. The capsule thus measured is replaced by a capsule 3 to be adjusted, and an efficiency measurement is carried out by supplying it with the frequency generator 5. The result of the measurement displayed by the measurement device 8 allows to locate the template, that is to say the range of the measuring device in which the readings of the capsules to be adjusted must be made for the capsules to be declared correct.

 Figure 2 shows in partial section and in elevation, part of the apparatus of Figure 1. There is the coil 2, the capsule 3 and the artificial ear 6. The coil 2 is a solenoid inside which the capsule and the artificial ear are placed. Around the coil 2 is provided a cooling circuit 20 which is a coil traversed by water. The coil 2 and the cooling circuit are embedded in a resin 21, and the assembly is held in place by a flange 22 fixed on a base 23, made of wood for example, which rests on a table 24 by means of a layer of foam 25. Inside the coil 2, a support 26, cylindrical, hollow, is centered relative to the coil cooling circuit assembly by a centering ring 27. This support, made of non-magnetic metal, is fixed to the table 24 by the bolts 32, made of non-magnetic metal. An upper part 34 of the support 26 is removable and fixed to the support 26 by bolts 35 of non-magnetic metal. The support 26 contains the artificial ear 6 above which is placed, in a pavilion 28 of a telephone handset, the capsule 3, which is centered in the pavilion by a non-metallic ring 29 preferably. The capsule 3 is held in position by a quick clamping device 30 of any known type, in order to allow a rapid change of capsule. A filter grid 31 is interposed between the artificial ear 6 and the pavilion 28.

 Inside the support 26, therefore below the artificial ear 6, a printed circuit board 33 is placed on the table 24. On this printed circuit board are fixed the circuits and components constituting the amplifier 7.

 During magnetization, the current in the coil 2 must be sufficient for the magnet of the capsule 3 to be saturated, the applied current preferably corresponding to full alternation of the alternating network. For the different demagnetizations carried out for the adjustment of the capsule, it is possible, thanks to thyristor 12, to let the current pass during a fraction of an alternation, and thus to delete the adjustable resistance R, or not to modify the value of this resistance which will be adjusted to obtain the current necessary for the saturation of the magnet of the capsule. The magnetizing and demagnetizing fields are therefore generated by a current pulse in the coil, pulse of duration equal or less than 10 milliseconds, the duration therefore the amplitude of each pulse generating a demagnetizing field being a function of the amplitude desired for the demagnetizing field.

 The adjustment of the capsules can be carried out automatically, using a microprocessor which receives from the amplifier 7 a measurement signal which it compares to the "template" corresponding to the type of capsule to be adjusted; depending on the result of this comparison and if necessary, the microprocessor triggers a demagnetization operation followed by an efficiency measurement operation. Of course, it is the microprocessor which, as soon as a capsule to be set is set up, will trigger the magnetization operations at saturation of the magnet, then demagnetization and measurement which follow; the microprocessor will therefore control the control circuit 14 of the thyristor 12 and the inverter 13 which will advantageously be of the electronic type. The adjustment operations are stopped as soon as a capsule is declared good.

Claims (9)

1 / Method for adjusting an electromechanical transducer capsule comprising a permanent magnet motor of remanent magnetic material and a moving coil integral with a membrane, characterized in that a capsule assembled inside is introduced a solenoid, which is carried out as follows: magnetizing to saturation the remanent magnetic material of the capsule, applying to the remanent magnetic material a pulse demagnetizing field of amplitude less than the coercive field of the magnetic material, performs a measurement of effectiveness of the capsule by applying an electrical signal to it in a determined frequency range and by measuring an acoustic signal emitted by the capsule, then repeating the demagnetization and measurement operations until the measurement of the acoustic signal falls within a predetermined measurement range, the demagnetizing field increasing from one operation to another. 2 / adjustment method according to claim 1, characterized in that the electrical signal consists of a continuous spectrum of weighted frequencies. 3 / adjustment method according to claim 1, characterized in that the demagnetizing field has a duration of less than 10 milliseconds. 4 / A device for adjusting a capsule for implementing the method according to claim 1, characterized in that it comprises a coil (2), in the form of a solenoid, supplied by a power source (1) delivering current pulses, an artificial ear (6) inside the coil, a frequency generator (5), an amplifier (7) and a measuring device (8), the capsule (3) to be adjusted being placed at the - above the artificial ear, inside the coil. 5 / adjusting device according to claim 4, characterized in that the artificial ear (6) is of the condenser microphone type. 6 / adjusting device according to claim 4, characterized in that the artificial ear is fixed inside a support (26) cylindrical, hollow, centered with respect to the coil (2) and that a flag (28) is fixed above the artificial ear in an upper part (34) of the support, said horn (28) receiving a capsule held in place by a quick clamping device (30). 7 / An adjustment device according to claim 4, characterized in that the frequency generator is a white noise generator. 8 / adjusting device according to claim 4, characterized in that the measuring device (8) is a logarithmic voltmeter. 9 / adjusting device according to claim 4, characterized in that the measuring device (8) is a microprocessor which compares each measurement to a template, and which automatically controls all the adjustment and measurement operations.