KR940005863B1 - Transducer - Google Patents

Abstract

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Description

Transducer

1 is a perspective view of a transducer of the configuration according to the present invention.

2 is a cross-sectional view of the transducer of FIG.

3 is an enlarged view of the sleeve and coil of the transducer of FIG. 1 and the magnetic circuit components associated therewith.

4 is a diagram illustrating the arrangement of coil windings on a sleeve according to the present invention.

* Explanation of symbols for main parts of the drawings

10 transducer 11 frame

12: Frangi 13: The sleeve

14: diaphragm 15, 16: coil

17, 18: magnetic circuit 19, 20: end

21, 22: pole ring 23: ring magnet

24: conversion ring 25: conversion plate

26: elastic pad

The present invention relates to transducers, and more particularly to transducers, such as loudspeakers, which convert electrical signals into corresponding vibrational air movements.

It is well known that transducer systems, particularly those that convert electrical energy into mechanical energy, are inefficient in operation. In general, only a small fraction of the total electrical energy supplied to such transducer systems is actually converted and used as mechanical energy. When electrical energy is supplied in the form of a signal required by the transducer system, the output signal in the form of converted energy does not exactly match the input signal. The difference in the amount of signal between the input signal and the output signal is distortion, which is a component of the transducer system.

Moreover, if the transducer is typically operated with the components of a large system, the inefficiency in converting from one energy form to another will further increase the distortion of the large system.

For example, in order to form electrical energy from the amplifier into vibrating air movements (ie voice pressure waves), an inefficient loudspeaker that converts it into mechanical energy can thus be opposed to the opposite electrical signal from the amplifier to achieve an acceptable voice pressure level. The energy will need to be sent out, increasing the distortion introduced into the overall system by the amplifier.

As is known, a transducer, generally used as a loudspeaker, has a driving assembly that receives an electrical signal and a diaphragm that is connected to the driving assembly to vibrate by the received signal. The driving assembly, that is, the voice coil, usually has a coil wire and a magnet core installed in the coil wire to move in response to the magnetic field generated by the energized coil. In this case, the coil is fixed to the center point of the diaphragm, while the diaphragm is hinged at its outer edge. In other cases, it is known to have a diaphragm actuated by a force that softens the edges. One such system is disclosed in US Pat. No. 3,919,566. However, in these systems, the diaphragm operates in an unbalanced form that is easily twisted. Other similar systems are described in US Pat. Nos. 3,012,107, 2,535,757, 2,520,646. It will be appreciated that any improvement in the mechanical benefits of the transducer system here can be used only for the particular type of mechanical energy applied.

In other words, in a transducer system that generates a mechanical motion of a reciprocating shaft in response to an electrical input, the deviation in mechanical benefit often results in a short, strong stroke for long and weak strokes, or vice versa. The practical work defined by the product of the mechanical force and the distance the force acts will be the same, indicating that no fundamental improvement in conversion efficiency has been achieved.

In many cases, the structure of a loudspeaker is generally focused as a primary concern on the mass of the diaphragm, an element that is directly coupled onto the air medium. Although the development of useful low mass diaphragms is a valuable design goal, advances in materials science and manufacturing methods have made it possible to produce small diaphragms in weight for driving assemblies.

As efficiency is known as the ratio of voice coil weight to diaphragm weight, if effective operation is maintained, the weight of the drive coil should also be reduced as the weight of the diaphragm is reduced. This is particularly important in soft-acting transducer systems, where the driving coil is located at the edge of the diaphragm, thereby reducing the mechanical advantage of the coupling of low frequency signals that are loaded at the center of the diaphragm. Come.

As is evident in this interpretation, although the mechanical advantage of an electromagnet transducer operating at high frequencies is improved by softening, the benefit is the maximum in the region near the center of the diaphragm, which is the furthest from the softening. Producing air pressure cannot be truly preserved for low frequencies. As such, the operational efficiency of the electromagnetic acoustic transducer system at high acoustic frequencies spread along the surface of the transducer diaphragm can be improved by making a small mass soft operating system. Moreover, this reduced mass of the actuation means improves the efficiency of the transducer at low frequencies because the diaphragm is induced to push the air axially over the entire width of the diaphragm, resulting in an immediate low frequency acoustic pressure wave. The drive coil appears at one end of the radial moment arm while the air load is at the other end.

Accordingly, one object of the present invention is to provide one electromechanical transducer system with improved energy conversion efficiency, and another object is to provide an electron with high agreement between the amount of each input signal and output signal. To provide a mechanical transducer system.

Another object of the present invention is to provide a transducer system that is economically manufactured, easy to assemble, and also eliminates distortion in the transducer.

Another object of the present invention is to eliminate torsion in the loudspeaker, and also to provide the same but separate electromagnet circuit for each direction of the alternating current.

In summary, the present invention relates to a sleeve, a diaphragm fixed to a central plane within the sleeve, and a symmetrical relationship to the sleeve, so that the sleeve and the diaphragm are linearly reciprocated to balance and torsion. It is to provide a transducer, such as a loudspeaker, formed by an electromagnetic means that will generate a sound free of this.

Means for reciprocating the sleeve and the diaphragm include means for defining a pair of coils wound on the sleeve in a symmetrical relationship with respect to a center plane and a pair of armature circuits arranged in a symmetrical relationship with the center plane. Include. The coils are evenly wound to exert electromagnetic forces of the same magnitude and the same direction in response to the alternating current supplied to the coils while the respective magnetic circuits are disposed in one of the respective coils.

The arrangement of the coil and magnetic circuit for the sleeve and diaphragm improves the high and low frequency operation of the acoustic transistor by providing an edge operating system, the system having less mass and with lower mechanical energy than in prior art systems. More effective at converting

By winding the coils in a symmetrical relationship, in particular by having a mirror image relationship with each other, isomagnetic equilibrium is obtained in the diaphragm plate. The magnetic circuit is of a type that produces magnetic field flux across the air gap radially, respectively, in which a portion of the sleeve composed of associated coils is arranged. When the coil is biased by applying an electrical signal to the coil end or terminal, the corresponding mechanical motion of the sleeve occurs in a direction parallel to the central axis of the magnetic circuit.

In this configuration, the transducer, that is, the loudspeaker, is symmetrically applied to the electromagnetic force induced on the sleeve, that is, it is possible to generate a distortion-free sound by a balanced method. This allows the diaphragm to reciprocate, i.e., oscillate, and in a balanced manner generate a true acoustic wave corresponding to the received electrical signal.

In addition, with this structure, the combined mass of the coils of the mirror images becomes smaller than the mass of a single coil used in a known transducer system for generating the same energy conversion efficiency. This improves the conversion efficiency over conventional single coil systems having the same mass.

In addition, the reduced effective equivalent mass of the soft actuation system raises the mechanical resonance frequency of the sleeve, thereby improving the ability of the sleeve to generate a high frequency signal across the surface of the diaphragm. In addition, the reduced sleeve mass for a given conversion efficiency reduces the effective moment arm at low frequency, thereby further improving the mechanical benefits and efficiency at low frequency operation.

These and other objects and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Referring to FIG. 1, the transducer 10 is generally cylindrical in shape with both openings. As shown in FIG. 2, the transducer 10 has a mounting frame 11 in the center so that the transducer 10 can be mounted in a suitable housing or support. The frame 11 has an annular shape and has a pair of flanges 12 having a separation space inwardly. A thin walled flangeless sleeve 13 is fitted inside the frame 11 and a flat disk-shaped diaphragm 14 is fixed on the sleeve 13 center plane inside the sleeve 13. .

The sleeve 13 is made of a suitable material such as brass, while the diaphragm 14 is made of a suitable material such as a metal plate, for example brass plate.

As shown in FIG. 2 and FIG. 3, the electromagnetic means reciprocates the diaphragm 14 and the sleeve 13 in a horizontal manner in a transverse direction with respect to the center plane of the sleeve 13 to generate a balanced sound. Is provided in the transducer 10 for the sake of brevity. The means comprises a pair of coils 15, 16 wound evenly on the sleeve 13 symmetrically with respect to the diaphragm 14, and are also arranged symmetrically with respect to the diaphragm 14. And a pair of sperm magnetic circuits 17 and 18.

The coils 15 and 16 are the same in response to the alternating current applied to the coils 15 and 16, and the same on the sleeve 13 so that electric force in the same direction is generated. Winding. As shown in FIG. 4, the equally wound coils 15 and 16 are wound to form symmetrical mirror shapes with each other. Only two windings are shown for each coil in the figure to clarify the winding direction.

Each coil 15, 16 had a pair of ends or terminals 19, 19 ', 20, and 20', respectively, from the sleeve 13 into the frame 11 from the sleeve 13; It extends to the appropriate public tab (not shown). Then, the current inflow terminals 19 ', 20' of each coil are provided at the lower part of the winding coil. The coils 15 and 16 are connected in parallel by supplying electrical signals from the appropriate common power supply (not shown) to the terminals 19, 19 ', 20 and 20' of the tap (not shown). Is taxed. The symmetrical arrangement causes the currents flowing through the respective coils 15 and 16 to have the same distribution.

In this embodiment, the current terminals for the two coils are marked adjacent to each other.

The positional displacement of the terminals 19, 19 'with respect to the terminals 20, 20' will establish the manufacturing method and the signal conversion requirements.

Referring to FIG. 2, the magnetic circuits 17 and 18 may be spaced apart from each other in the frame 11, and may have opposite relations with the flange 12. Each circuit 17, 18 comprises a pair of pole rings 21, 22 arranged concentrically spaced about each of the coils 15, 16. .

One pole ring 21, for example, acts as the N pole while the other pole ring 22 acts as the S pole. In addition, each of the circuits 17 and 18 includes an annular magnet 23 fixed to the outer pole ring 22 and a conversion ring 24 fixed to the inner pole ring 21, and the magnet 23 and the conversion ring 24. It includes an annular conversion plate 25 fixed to). As shown, the conversion plate 25 forms a circular opening in communication with the diaphragm 14.

The pole rings 21 and 22 are installed in the sleeve 13 and the respective coils 15 and 16 and define air gaps through which magnetic flux lines flow. The magnetic flux thus flows between the pole rings 21, 22 via the magnet 23, the conversion plate 25, the conversion ring 24, the magnet 23, the pole ring 24, and the like. The conversion plate 25 is made of a low loss magnetic material The conversion ring 24 is made of cast iron.

A pair of elastic pads 26, for example a compressive fiber, is installed to center the diaphragm 14 between the pole rings 21. This pad 26 has a sufficient elastic force to prevent causing a deterioration effect on the reciprocation of the diaphragm 14 during operation.

In operation, the electrical signal is supplied to the terminals 19, 19 ', 20' and 20 'of the two coils 15 and 16 in the form of alternating current. Thus the signal is split into two balanced currents, which pass through coils 15 and 16 and interact with the magnetostatic lines generated across pole rings 26 and 22.

As a result, an electric force is generated to move each of the coils 15 and 16, that is, the slide 13. These forces are directed in the same direction, for example the right direction in FIG. 2, so that the sleeve 13 and the diaphragm 14 move in the right direction. Since the current is alternating current, it is made by changing or changing the electric force. As a result, the sleeve 13 and the diaphragm 14 are moved to the left as shown in FIG. 2, thereby linearly reciprocating the diaphragm 14.

Note that the width and flux density of the magnetic field depends on the width and size of each of the winding coils 15 and 16. In one embodiment, the inner pole ring 21 has an outer diameter of 3.593 inches, while the outer pole ring 22 has an inner diameter of 3.625 inches, thereby forming an annular air gap of 0.032 inches.

The sleeve 13 has an inner diameter of 3.607 inches while the coils 15 and 16 have an outer diameter of 3.643 inches, thereby giving a gap of 0.032 inches from the outer pole ring 22. The coil can be formed with lines of 0.003 inches wide and used for the operation of the diaphragms of the two coils 15, 16 and the two magnetic circuits 17, 18 to achieve balanced operation. .

If a single magnetic circuit is used for two coils 15, 16 or if two magnetic circuits 17, 18 are used with one symmetrical array of coils, an unbalance will occur. will be. In other words, this imbalance will limit the current from the occurrence of motion to the maximum potential. In addition, the lengths of the two identically parallel coils 15 and 16 reduce the time required to pass their lengths compared to a single conductor having the same overall length. That is, the time is reduced to about 1/2. This results in an increase in efficiency with respect to the transducers employing such parallel arrangements.

The present invention having the transducer provided as described above enables the diaphragm to be reciprocated in a balanced manner when used in a loudspeaker or the like, and can generate distortion-free acoustic waves, and as a result, it is possible to produce a sound having a given intensity. Less power is required.

The transducer 10 may provide a suitable diffusion cover, such as a grid, at the open end for the diffusion of acoustic waves generated.

Claims (13)

A sleeve 13 and a diaphragm 14 whose surface is perpendicular to the longitudinal axis of the sleeve 13 and which is supported on its central plane within the sleeve 13, wherein the sleeve 13 is provided. In the transducer further comprising electromagnetic means (15), (16), (17), (18), functionally arranged to cause linear reciprocation of the diaphragm (14) and the diaphragm (14). The first and second coils 15 and 16 disposed on opposite sides of the center plane and wound so as to be mirror-symmetrical with respect to the center plane, the sleeve when the transducer is in use ( 13) is equal to each of the transducers, characterized in that configured to obtain a balanced and torsion-free speech output under the same direction of force. The method of claim 1, wherein alternating current is supplied from the common power source to the first and second coils (15) and (16), wherein the electromagnetic means are symmetrical with respect to the center plane. Transducer, characterized in that it further comprises a pair of static magnetic circuits (17, 18) each disposed in). The transducer as claimed in claim 1, wherein the diaphragm (14) consists of a flat disk. 4. The transducer as claimed in claim 3, wherein the disk is made of metal. The transducer as claimed in claim 2, further comprising a frame (11) for fixedly mounting said magnetic circuit (17). 6. The magnetic circuit according to claim 5, wherein each of the magnetic circuits (17) and (18) has a pair of pole rings (21) having a uniformly spaced concentric circle arrangement in which one end of the sleeve (13) is arranged concentrically therebetween. A transducer, including (22). 7. An annular magnet (23) in which the respective magnetic circuits (17) and (18) are fixed to one of the pole rings (21) and (22), and the other pole rings (21) and (22). And an annular conversion plate 25 fixed to the magnet 23 and the conversion ring 24 and configured to define an opening associated with the diaphragm. Transducer. 7. The transducer as claimed in claim 6, further comprising at least one elastic pad (26) for centering the diaphragm (14) with respect to each of the pole rings (21, 22). The transducer as claimed in claim 1, wherein said electromagnetic means are arranged to reciprocate said sleeve (13) in the transverse direction with respect to said plane. 10. A pair of coils (15) and (16) according to claim 9, wherein said electromagnetic means has an symmetrical mirror symmetry with respect to said center plane so as to pass alternating current in parallel from a common power source. Transducer, characterized in that configured to include. 11. Transducer according to claim 10, characterized in that the sleeve (13) is configured to be flangeless. 2. A sleeve according to claim 1, wherein said electromagnetic means has a pair of ends (19) and (19 ') extending from said sleeve (13) so as to generate electrical force by conducting alternating current electricity. A first wire coil 15 wound on 13, first means 17 provided on one side of the center plane defining a magnetic circuit for the first coil 15, and the first The first coil has a pair of ends 20, 20 'extending from the sleeve 13 in which an alternating current is conducted so that an electric force directed in the same direction as the electric force of the coil 15 is applied. A second wire coil 16 wound on the sleeve 13 on the opposite side of the plane in a mirror symmetric relationship with respect to the opposite side of the plane to define a second magnetic circuit with respect to the second coil 16. Second means provided and the first coil 15 and the second coil 16 Transducer comprising a common AC power supply connected to. The method of claim 1, wherein the electromagnetic means, at least one magnetic flux conversion to create a long annular air gap to cause a magnetic flux in each of the permanent magnet 23 and the sleeve 13 disposed therein First and second magnetic circuits having elements 21, 22, 24, and 25, which are installed on respective ends of the sleeve 13, are wound in the same mirror image and are common to each other. And first and second coils 15 and 16, which are wound so that alternating current is conducted in parallel from the power source, and a frame 11 for supporting the first and second magnetic circuits having a mirror image relationship therebetween. Transducer, characterized in that.

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