US3283086A

US3283086A - Versatile extensive area sound reproducer or audio transducer

Info

Publication number: US3283086A
Application number: US288282A
Authority: US
Inventors: Willis F Evans
Original assignee: Individual
Current assignee: Individual
Priority date: 1963-06-17
Filing date: 1963-06-17
Publication date: 1966-11-01
Anticipated expiration: 1983-11-01

Description

Nov. 1, 1966 w, v Ns 3,283,086

VERSA'I'ILE EXTENSIVE AREA SOUND REPRODUCER OR AUDIO TRANSDUCER Filed June 17, 1963 2 Sheets-Sheet 1 FIG.|

INVENTOR WILLIS E EVANS ATTORNEYS W. F. EVANS Nov. 1, 1966 VERSATILE EXTENSIVE AREA SOUND REPRODUCER OR AUDIO TRANSDUCER 2 Sheets-Sheet 2 Filed June 17, 1963 FIG.7

FIG. 6

FIGS

INVENTOR WILLIS F. EVANS ATTORNEYS FIG.8A

United States Patent 3,283,086 VERSATILE EXTENSIVE AREA SOUND REPRO- DUCER OR AUDIO TRANSDUCER Willis F. Evans, 2 Cousineau Road, Navy Point, Warrington, Fla. Filed June 17, 1963, Ser. No. 288,282 Claims. (Cl. 179115.5)

The present invention relates to the transducer field in general and more particularly to the provision of novel speaker or microphone embodiments susceptible to incorporation into entertainment type instruments such as home TV, high fidelity or stereo systems, and the like. Also, other commercial and military use is contemplated.

The transducer of the subject invention is of the type capable of producing audio sound output in response to applied audio signals or the inversion thereof; namely, providing an output audio frequency voltage or current in response to actuation by sound wave energy. It will be described in detail in connection with the speaker use; it being borne in mind that the principles are applicable to the microphone use.

Over the years speakers have become increasingly more complex devices for the reason that compensation with respect to highs and lows and other characteristics have been added, along with frequency extenders and various other improvements which has resulted in a modern day relatively complex device. This applies equally to the electro-dynamic loud-speaker employing the cone shaped diaphragm driven by a voice coil, disposed in a constant magnetic field, as well as the well known electro-dynamic loud-speaker of the type having a periphery clamped diaphragm with annular ribs or ridges and employing conductors situated in magnetic fields for power drive movement.

An important object of the present invention is the provision of an extremely simple and readily fabricatable speaker or microphone, exhibiting even improved characteristics over those commonly found in commercial devices, as will be particularly pointed out. The simplicity of the structure is occasioned, not only by fewer components, but by the simplest of components.

For example, the diaphragm rather than being of the cone or annular ribbed type i flat. The driving energy is eifective generally perpendicularly throughout the area of the diaphragm rather than concentrated at the apex of a cone or within a ribbed channel about a small portion thereof, as in presently utilized diaphragms.

The voice coil or its counterpart is preferably deployed on the diaphragm, as a printed circuit of various configurations to be described, which may be disposed on one or both sides thereof in the form of a continuous conductor, as series aiding coils or as parallel coils.

The magnetic field for the voice coil may be produced by the simplest of permanent magnets in one embodiment, or by a novelly arranged cooperating magnetic system in another embodiment.

In either event, the thinnest of speakers may be produced from the smallest to large sizes heretofore practically unavailable. as single or multiple cabinet wall faces for entertainment reproducing devices or as detachable picture-like speakers suitable to stereophonic orientations and modern decor up to and including room wall sizes.

They are particularly suited for use The invention finds utility in commercial and military the detector may be submerged to great depths without pressure influence because of the fiat diaphragm construction and because a pressure resisting external housing is unnecessary, the operative force connection being simply magnetic fields for use underwater. or in the atmosphere.

More particularly, the diaphragm may comprise a suitable fabric, preferably in circular configuration, having silkscreened thereon (or otherwise following printed circuitry technique deployed thereon) a continuous conductor voice coil in discrete geometrical configuration form. In one embodiment this circuit takes the form of concentric circles where as in another embodiment a spiral deployment is utilized. Other geometrical patterns may follow the principles herein set forth. In any event, the magnetic field is arranged to encompass the voice coil configuration in a flux pattern approaching the greatest uniformity available in a practical device.

The diaphragm is preferably peripherally suspended in a manner leaving it free to float, such that mechanical resistance is Since the entire diaphragm moves as essentially a single unit, whether a large or small diaphragm is employed, uniformity of mass will be distributed over the entire diaphragmatic surface rather than being concentrated at the center or in the form of widely spaced rings extending to the periphery, Naturally, the inverse is true also when the diaphragm is employed as a microphone pick-up for remote sounds. I

The voice coil may be comprised of a continuous conductor in either embodiment. It is, of course, desirable that the single source or concentric source magnetic field or fields influence the entire length of the conductor in an additive manner such that the elemental currents developed will flow in the same direction.

The single conductor may comprise a double spiral configuration, which is wound in like direction on both surfaces of the diaphragm, when viewed directly (not through a surface). For example, if the conductor is laid down in a counter-clockwise spiral on a first surface of the diaphragm, it may penetrate the diphragm at the outer edge and form a spiral on the reverse side, also wound in a counterclockwise direction when viewed directly. It will be realized that such spirals are not interleaved but, in fact, are oppositely Wound. However, when a single source magnetic field is deployed adjacent to either surface, additive currents are developed along the increments of the spirals such that they may be considered as being series aiding voice coils with external terminals being provided by the ends of the single conductor disposed at the inner areas of the spirals.

Alternatively, when one spiral is wound in a counterclockwise direction and the other in a clockwise direction, each as viewed directly, then the conductor may penetrate the diaphragm near the center and an external lead is brought out from this center point to comprise one termi; nal, the other terminal being connected to the free ends of the spirals such that the two spiral configurations are connected in parallel for increased current production. It will be understood that the outer ends of the conductor may also penetrate the diaphragm and be connected to an external lead. Alternatively the spirals may be laid down separately and the ends brought out separately to provide two coils, connectible in series of parallel additive relation. The arrangement also, of course, assumes a single uniform magnetic source in juxtaposition with one of the diaphgram surfaces and permits the spirals to be interleaved.

In the concentric circular deployment, both series and parallel arrangements are contemplated, each with respect to a single magnetic source and also with respect to a multiple magnetic source of a concentric magnet type.

Considering first the single source magnetic field, the continuous conductor may be laid down in like directions on both sides of the diaphragm, when viewed directly, to provide a series aiding configuration. For example, the conductor may have a first terminal near the outer edge of the diaphgram and form concentric circles decreasing in diameter, in a counter-clockwise direction, toward the center of the diaphragm where the conductor may penetrate to form interleaved concentric circles on the opposite side of the diaphragm, also Winding in a'counterclockwise direction, when the diaphgram is turned over and viewed directly. This configuration terminates in a second external terminal disposed outwardly of the concentric circles.

When the multiple magnetic source is employed, a like deployment of the conductor admits of paralleling of the two concentric configurations to provide increased current output. In other words, in the situation where the conductor extends from an external terminal in a counterclockwise diminishing configuration to penetrate the diaphragm at its center and then form a counterclockwise expanding interleaved configuration to terminate in an external terminal, the two external terminals are connected together to form one ouput terminal with the other output terminal being joined to the middle point of the conductor (the point of penetration between the configurations).

The other alternatives contemplate the use of oppositely wound concentric circles conveniently connected in parallel for use with a single source and oppositely Wound concentric circles conveniently connected in series at the outer edge for use with a multiple or concentric magnetic field source.

The interleaving feature of the embodiments described enables the voice coil to approximate a thin pliable metal disc insofar as the magnetic field is concerned, thereby offering a maximum number of conductive paths distributed throughout the extensive area within the magnetic field influence. As a matter of fact, preferably the interleaved concentric circles and spirals actually overlap somewhat such that the diaphragm presents no uncovered areas throughout the configurations.

These particular deployments enable the optimum use of practical magnetic sources to provide a practical commerical device. For example, the spiral deployment outlined is readily operative in a uniform magnetic field which distributes the effective magnetic forces across the diaphragm in a uniform manner. As a matter of fact, when a single two pole concentric magnetic field approach is utilized consisting of, for example, a central core of one polarity and an annular ring of another polarity, the spiral type voice coil receives substantially uniform exposure. In the case of such magnetic sources where it is found that, as a practical matter, a greater flux concentration occurs near the center of the magnet, it has been founddesirable to graduate the spiral deployed on each side of the diaphragm to permit some spacing (uncovered diaphragm) in the central area where the flux is concentrated with increasing coverage in the decreasing regions thereby compensating to yield uniform diaphragm actuation.

The concentric circular diaphragm is particularly suitable to use with a multi-pole concentric circle magnet,

adjacent magnetic structures being oppositely polarized. For example, a core in the form of a north pole is surrounded by an annular maget polarized south, in turn surrounded by a magnetic north, etc. In this manner, each incremental region of the diaphragm is exposed to the flux (due to adjacent annular poles) and the diaphragm is substantially uniformly actuable.

With the foregoing in mind, it is among the objects of this invention to provide a novel and effective audio transducer.

It is isv a further object to provide such a transducer susceptible to extensive dimensions for greater sensitivity in the detection function and greater moving power for the sound dissemination function.

A still further object is the provision of such an'audio transducer capable of being epoxied and subjected to adverse conditions of the elements without concern as to corrosion or pressure differential problems.

It is yet another object of the invention to employ uniquely cooperative components which are readily manufacturable or commercially available.

The invention will now be described in connection with its application to certain perferred embodiments explained in detail in conjuction with the appended drawing wherem:

FIG. 1 is a view in elevation of a typical transducer, operable in accordance with the principles of the present invention.

FIG. 2 is a View in end elevation of the structure of FIG. 1. 7

FIG. 2A is a view of a portionof the structure of FIG. 1 or FIG. 2, greatly enlarged and in section to show how the continuous conductor is laid down in interleaved fashion relative to opposite .sides of the diaphragm.

FIG. 3 is a view in section of the apparatus of FIG. 1.

FIG. 4. is a further detailed view of a structure of a different embodiment.

FIG. 5 .is a view in perspective of a suitable magnetic source for use with certain embodiments of the invention.

, FIGS. 6 and 7 show respectively elevational views of a concentric circular deployment of a continuous conductor starting on one side of the diaphragm and extending along the, reverse side thereof.

FIG. '8 is an elevationalv view of a spiraltype deployment.

FIG.8A is a schematic illustration of an alternative type spiral configuration, and

FIG. 9 is a schematic illustration of graduated oppositely wound spiral configurations.

Referring now to FIG. 1 there is shown generallya hoop or supporting structure 11 having a central open- .ing 13 for accommodating a thin diaphragm 15. The

diaphragm is maintained in a taut condition by flexible resilient supporting strands 17, laced or grommeted between the periphery of the disc 15 and the supporting structure 11. A voice coilor continuous conductor 19 is shown partly deployed on the visible surface of the diaphragm 15, the visible end of the conductor 21 being brought out near the upper periphery of the diaphragmwith the remainder (not shown in FIG. 1) of the conductor penetrating the diaphragm 15 in the center thereof to develop a further configuration 19 (FIG. 2) on the reverse side of the diaphragm 15. Various modifications of the configuration will be described in detail hereinafter.

FIG. 2A is a view of a portion of the structure of FIG. 2, greatly enlarged to show how the continuous conductor 1949 is laid down in interleavedfashion relative to opposite sides of the diaphragm 15. It will be noted that the width of the conductor 19-19 exceeds the width of the spacing between adjacent turns thereby providing an effectively, and completely metalized disc.

FIG. 3 is a view of the structure of FIG. 1 with a magnetic source 25 in association therewith. The diaphragm 15 is shown tautly stretched by supporting strands 17 such that the magnetic source 25,-consisting of a central core 27 and annular pole piece 29,is'disposedin fixed relation thereto being retained by, for example, a portion of the supporting structure 11. .If it is considered that the core 27 is a north pole and the annular ring 29 the south pole, then magnetic fiux is caused to flow out of the north pole, through the diaphragm, and back into the south pole. Obviously, the magnetic source 25 may be of the permanent magnet or electric coil type andin either event is primarily used to provide a sub stantially uniform flux field, as shown by the lines 31 effective on the area of the conductor configurations 19-19.

Typical materials may include gold for the conductor 19-19, which may be laid down by printed circuit techniques. The diaphragm 15 may comprise a suitable synthetic membrane of 0.015 inch in thickness. By way of example, the outside diameter of a typical embodiment would measure 12-24 inches or longer for the diaphragm with the conductor deployment occupying some 8-16 inches or more of the central portion. In such a model the thickness of the conductor may be of the order of 0.002 ,inch with a typical conductor width being inch, more or less.

The disc or diaphragm 15 may be of synthetic membrane and the disc and conductor deployments may be cemented to a thin A; inch wooden skin for certain applications. Also a thin flat skin of speaker cone paper may be attached to the entire surface of the membrane along either side of the double deployed circuit by adhesive to provide damping effects. The resilient material 17 may be bunge cord threaded through grommets to render the membrane free floating. For other applications,

the membrane may be attached to supporting structure in the form of a hoop which also provides high damping.

The conductor 19-19 may be deployed in various configurations, such as those depicted in FIGS. 6 through 9, now to be described.

Considering first the concentric circle configuration of FIGS. 6 and 7, it will be noted that when the diaphragm 15 is viewed from one surface, as in FIG. 6, the conductor 19 traces out concentric circles in a clockwise direction toward its center from external terminal 41 of the diaphragm. The conductor is shown penetrating the diaphragm center to come out on the backside of diaphragm 15 as conductor 19 extending outwardly in increasing diameter circles to provide terminal 43. Viewed from its surface, the direction of winding is opposite to that of FIG. 6, being counterclockwise from outside to inside. The interleave of the conductor circles on opposite surfaces is apparent from a comparison of FIGS. 6 and 7, as is also the effective overlap.

In operation, the diaphragm 15 is deployed in proximity with a magnetic source of, for example, the concentric pole type of FIG. 5. This deployment is shown in exaggerated partial view in FIG. 4, wherein it may be seen that the concentric

magnetic poles

45, 46, 47 and 48 occupy positions relative to the conductor 19-19' to establish flux paths through the conductor to develop current in an additive direction, the flux lines encircling the conductor portions on the opposite halves of diaphragm 15 from opposite directions. Thus, it may be appreciated that the concentric poles of the magnetic source are quite thin, but the structure is practical of manufacture.

Use of a multiple-concentric magnetic source with the oppositely wound concentric circular deployments results in the production of currents in opposite directions in the conductors 19-19. They may be paralleled by joining terminals 41 and 43 as one outside terminal, with lead 44 (to the center point of either conductor 19 or 19') serving as the other output terminal. They may be connected in series conveniently by letting conductor 19-19 be continuous at the outer edge to penetrate diaphragm 15 at the location of terminals 41 and 43, with the output terminals then both being brought out from the center of the respective surfaces, as by conductors such as 44. In this event the single conductor 19-19 has its free ends at the respective centers and the external connections may be made to either side or may both be on a single side of one of 19 or 19' penetrates the central area.

The concentric circular type deployment of the conductor 19-19' is also cooperative with the magnetic source of the single variety (single north and south poles) wherein each conductor element is exposed to the substantially uniform field. For the oppositely wound conductors 19-19, the use of a single source produces 6 currents in opposite directions along adjacent layers and accordingly it is desirable to connect the individual conductors 19-19 in parallel. This is readily achieved by permitting penetration at both the outer and inner positions. Then connections are made to both points of penetration for paralleled coils. Alternatively, an outer end of one of conductors 19 or 19' may be joined to an inner end of the other to provide a series arrangement of the two coils.

The

conductors

19, 19 may overlap, as in FIG. 2A, or may :be spaced sufliciently to leave uncovered gaps, as in FIGS. 6 and 7, on the diaphragm surfaces.

The single source 25 is also preferably the type employed with the spiral configurations of FIGS. 8, 8A and 9. In FIGS. 8 and 8A, the conductor 19 is deployed on one side of the surface 15 as a spiral and the conductor portion 19 is interleaved therewith on the other surface of the diaphragm 15. While the conductor 19-19 \may be continuous as in FIG. 8A, where it penetrates the diaphragm 15 near the conductor midpoint and also near the outer edge of the spirals, it will be appreciated that the spirals may be each separate, as in FIG. 8, such that connection of corresponding ends 59-59 and 60-60 (of inner connections 61 and 62) may parallel the spiral circuits or connection of say inner end 60' to outer end 5'9 provides an additive series arrangement.

For practical reasons, the spiral type voice coil is interposed in a uniform type magnetic field, it being impractical to manufacture a spiral type magnet. The spirals of FIGS. 8 and 8A are interlaced because the spirals on opposite sides of the diaphragm 15 are wound in different directions, when viewed directly.

In FIG. 8A, the conductors 19-19 are shown penetrating the diaphragm at both inner and outer locations to comprise a closed loop of two coils. The

external terminal connections

65 and 66 then provide paralleling of the coils.

A graduated spiral configuration including like wound spirals is depicted in FIG. 9. The spirals are concentrated near the center as shown by the conductor 19-19 and adjacent turns are spaced further apart toward the periphery. This structure is suitable for cooperation with a typical magnetic source of the type shown in FIG. 3 at 25 wherein there is some flux concentration near the central core. The graduated deployment of the conductor tends to maintain the magnetic forces uniformly distributed across the diaphragm 15. Also, the arrangement of FIG. 9 depicts spirals wound in like directions such that no interlacing is presented. However, the coils are adapted to additive series use by letting conductor 19-19 be continuous by penetrating diaphragm 15 near the outer periphery with the inner ends being connected to external terminal connections 61 and 7 0.

While the invention has been described in connection with its application to certain preferred embodiments, it will nevertheless be appreciated that other modifications will be apparent to those skilled in the art from a reading of the description hereof and such modifications within the principles of the invention are intended to comprise a part hereof, and thus the scope is to be limited only by the appended claims.

What is claimed is:

1. An extensive area transducer comprising, in combination, a flat diaphragm; means for resiliently supporting the diaphragm in a taut state; a continuous conductor coil deployed on bot-h sides in spreading configuration from the central area of the diaphragm toward its edges; and means disposed adjacent one side of the diaphragm for producing magnetic flux lines linking substantially all increment-s of the conductor to generate current build-up therein upon relative movement between the flux lines and conductor coil.

2. The transducer of claim 1, wherein the means for producing the magnetic flux lines comprises a single magnet consisting of an annular pole and a central hub pole.

3. The transducer of claim 1, wherein the means for concentric magnets with adjacent magnetic poles ,being oppositely polarized.

4. An extensive area transducer comp-rising, in combination, a frame; a flat diaphragm; resilient means for supporting the diaphragm in a taut state relative to the frame; a continuous conductor coil deployed on both sides. in spread-out configuration from the central area of the diaphragm toward its edges; and means substantially coterminous with the configuration supported by the frame and disposed adjacent one side of the diaphragm only for producing magnetic flux lines linking substantially all increments of the conductor coil to generate additive current build-up therein upon movement of the conductor relative to the flux lines.

5. The transducer of claim 4, wherein the conductor coil is deployed in the form of graduate-d interleaving spirals respectively disposed on opposite surfaces thereof; the spacing between adjacent turns of the spirals increasing from the outer edge to the center; and including external connections to the innermost ends of eachspiral.

6. The transducer of claim 4, wherein the conductor coil is deployed in the form of interconnected substantially concentric circles with the circles .on one surface being disposed in interleaved fashion relative to the circles on the opposite surface; the width of the conductor coil exceeding the spacing between adjacent circles; and including external connections to the ends of the conductor.

7. An extensive area transducer comprising, in combination, a diaphragm; means for maintaining the dia-. phragm fiat and resiliently supporting it peripherally; a continuous conductor deployed on opposite surfaces of the diaphragm in the form of a spiral on each surface; said conductor penetrating the diaphragm at a location remote from the central portion of the diaphragm and said conductor having its free ends available for external connections; means supported in proximity to one of the flat surfaces of said diaphragm for directing magnetic flux therethroug-h to interlink the spiral lengths of the conductor with magnetic flux for producing a current in the conductor when relative movement is established between the diaphragm and said last-mentioned means.

8. An extensive area transducer comprising, in combination, a diaphragm; means for maintaining the diaphragm flat and resiliently supporting it peripherally; a continuous conductor deployed on opposite surfaces of the diaphragm in the form of a spiral on each surface; the

g: spacing between adjacent turns of the conductor being less than the width of the conductor to permit overlay of the spirals; said conductor penetrating the diaphragm at least once; means supported in roximity to one of the surfaces only of said diaphragm for directing magnetic flux therethrough to interlink the spiral lengths of the conductor with magnetic flux; said last-mentioned means being.

oriented to direct flux about the conductor for producing a current in the conductor when relative movement is established between the diaphragm and said last-mentioned means; and means for paralleling the spirals to add the currents produced in each.

9. An extensive area transducer comprising, in combination, a diaphragm; means for maintaining the diaphragm flat and resiliently supporting it peripherally; a continuous conductor deployed on opposite surfaces ofthe diaphragm in the form of a plurality of concentric circles on each surface with the circles of one plurality being interleaved relative to the other; said conductor penetrating the diaphragm at least once; means supported in proximity to one of the surfaces of said diaphragm for directing magnetic flux therethrough to interlink the circle lengths of the conductor with magnetic flux for producing a current in the conductor when relative movement is established between the diaphragm and said last-mentioned means; and means for connecting the plurality of concentric circles in one of series and parallel relation.

10. The transducer of claim 9 wherein the means for directing magnetic flux comprises a plurality of magnetic poles in concentric arrangement with adjacent poles being oppositely polarized;.the poles of one polarity being disposed in substantial alinement with the circular conductor segments on one side of the diaphragm and the poles of the other polarity being in substantial alinement with the circular conductorsegments on the opposite surface of the diaphragm.

References Cited by the Examiner UNITED STATES PATENTS 3,012,107 12/1961 Hanlet 179-1155 3,022,487 2/1962 Harris 179l15.5 3,141,071 7/1964 Rich 179115.5 3,164,686 1/1965 Tibbetts 1791l5.5

KATHLEEN H. CLAFFY, Primary Examiner.

F. N. CARTEN, Assistant Examiner.

Claims

1. AN EXTENSIVE AREA TRANSDUCER COMPRISING, IN COMBINATION, A FLAT DIAPHRAGM; MEANS FOR RESILIENTLY SUPPORTING THE DIAPHRAGM IN A TAUT STATE; A CONTINUOUS CONDUCTOR COIL DEPLOYED ON BOTH SIDES IN SPREADING CONFIGURATION FROM THE CENTRAL AREA OF THE DIAPHRAGM TOWARD ITS EDGES; AND MEANS DISPOSED ADJACENT ONE SIDE OF THE DIAPHRAGM FOR PRODUCING MAGNETIC FLUX LINES LINKING SUBSTANTIALLY ALL INCREMENTS OF THE CONDUCTOR TO GENERATE CURRENT BUILD-UP