SE447692B - DEVICE BY SPEAKERS - Google Patents

Description

»Area f« s ^ i = i. \,. 15 20 25 30 35 “___- l 'w i ...__ W âëå 2 rerat area. The shape of the diaphragm that I consider to be optimal and the connection point for the drive member that I think is the best, I have arrived at through extensive empirical experiments and are not based on any particular theory. These experiments have shown that several parameters must work together in order to achieve the best conditions. However, the crucial improvements are achieved if the edge of the diaphragm has an elongated round shape, for example elliptical, and if the drive means is connected to the diaphragm in an area which, projected perpendicular to the edge plane or base of the diaphragm, lies next to a first reference line points and also next to a second reference line which is perpendicular .cuts the first reference line midway between said points.

According to the chosen embodiment, the membrane has the main shape of an oblique cone, i.e. the shape of a non-double-curved body. However, I do not want to exclude that the membrane has a double-curved shape, as is per se common. When in this context the term "cone" is used for the membrane, the term "cone" should therefore not be given a narrow mathematical definition. The term cone is used instead as a general term for a more or less funnel-shaped speaker diaphragm, as is common in the art. On the other hand, I consider it very important, and probably a prerequisite for the good sound transmission of the drive means to the diaphragm, that the drive means, which consists of a voice coil, is attached to the diaphragm via a non-magnetic portion which tapers to a tip so that the oscillations to the diaphragm occur within a very concentrated area at the tip of the cone.

This area, hereinafter referred to as the "driving point", and consisting of the contact surface between the cone and the tapered vibration transmitting element of the drive means / voice coil, should not have a diameter or maximum extent exceeding 10% and preferably not exceed 5% of the maximum diaphragm extension in the edge plane. .

The membrane can be stiffened in different ways. According to the chosen embodiment, the membrane has been pre-stiffened by "plissing", ie by folds extending from the tip to the edge of the cone in a manner known per se. However, other stiffeners should also be conceivable. slsos * - f! E * ... äs-e t * --.... ~ ._._-..- ~ f _._._-... ...._ .. - _._ .. .. ..; __, ._..-___.,. __, -_. . _ .. p. t. h, -..._ ..,. , _ ..._ f _., .._, .., ... a ..._ _ 10 15 20 25 30 S5 447 692 axial stiffening ribs which extend along the cone in the same way as the "pleat folds".

A treble cone should be arranged inside the first-mentioned cone, which is hereinafter referred to as the main cone. The treble cone also has an oval shape.

The main cone and the treble cone are connected to each other in the drive point, which is common to the two cones. The driving point is so close to the edge of the main cone that the edge of the treble cone projected perpendicular to the edge plane of the main cone substantially extends to or past the edge of the main cone. It is important that the two cones do not disturb each other, as they oscillate within their respective frequency ranges. To prevent interference from occurring, the ability of the main cone to reproduce sound at high frequencies, ie within the treble range, should be prevented or attenuated. This can be done in a few different ways: - You can "verify" the main cone for frequencies within the treble range.

The vertebrae mean that the part of the main cone membrane that is close to the drive point is made heavier. This part, hereinafter referred to as zone D - the treble zone - roughly corresponds to the part "shaded by the treble cone. In order not to have the total mass of the main cone so large that the voice coil and magnet are not able to drive the cone to the required degree, ie the attenuation becomes too large, you can compensate for the vertebrae by reducing the mass of the remaining part of the main cone to a corresponding degree.In principle, you could have a lighter material in the parts of the main cone that are further away from the drive point, but then preferred by others a better alternative is therefore to perforate the main cone in suitable places, so that air can pass through, which in practice also gives a mass relief from the cone, which when it turns can be considered one with the nearest air volume integrated body.

- The main cone can be made of different materials in the treble zone D, the midrange zone M and in the parts furthest from the drive point, the baeregxsterlene I. Thus, the diocantonon D can be made of a material that does not reproduce treble frequencies (frequencies> 7 kHz). i x fff-.lvtes-a. 20 25 30 35. «W§1h ~ in ~ W .f« W j-à. .lïï »v11 447 692 The material in the treble zone must therefore be attenuating for these frequencies. At the same time, however, it must be so rigid that it can transmit the oscillations to the next zone, between register register M. 2 Å Preferably, you have the same base material in the entire main cone, for example "carbon fiber-reinforced plastic, a material combination that is light and stiff at the same time. frequencies within the treble range can be applied within the treble zone D to a silicone layer on both the front and back of the base material of the cone.Within the intermediate M you can apply a metal coating, register: and in the area furthest from eg an aluminum alloy, drive point, base register zone - B. the base material can be provided with a cellulose layer.

The tweeter cone can be made of a thin layer of aluminum with a thin crease, and like the main cone it is suitable o The device should be equipped in such a way that the oscillation of the main cone in the bearing register zone B is stimulated. no such incentive measures are taken. namely, the diaphragm of the main cone will primarily swing only in the areas near the drive point. This can be prevented, ie oscillations also in the base zone B can be stimulated in various ways; but can be made more flexible along the base regeneration zone by making a cone in this area in the area near the driving point ".¿ <.1 .._- you make it wide and / or by tilting the one-axis axis of the talc cone in the direction of the base zone.

Further features and advantages of the invention will become apparent from the claims and from the following description of a preferred embodiment. l y * k BRIEF DESCRIPTION OF THE DRAWINGS In the following description of a preferred embodiment, p will be referred to the accompanying drawing figures. of which,, ¶ 441 692 ¿Fig. 1 is a plan view of the device according to the invention, Figs. Fig. 2 forms a section II-II in Fig. 1 through a plane coinciding partly with the drive point and partly with said first reference line, Fig. 3 constitutes a perspective view of the device obliquely from the front, and Fig. 4 shows the device in a perspective view obliquely from behind, wherein in Fig. 3 and Fig. 4 certain parts have been removed in order that the material of the invention may appear better.

DESCRIPTION OF THE PREFERRED EMBODIMENT 4 In the figures, a first diaphragm, which forms the main cone of the loudspeaker, has been designated 1. A treble cone has been designated 2. This also consists of a diaphragm. The treble cone 2 is arranged inside the main cone 1 and is connected to the main cone in the common, so-called drive point 3. The main cone 1 is suspended in a chassis 5 by the so-called cone suspension 4.

The edge of the main cone 1 has been designated 6. The edge 6 forms the boundary between the rigid, sound-emitting membrane of the cone 1 and the flexible, non-sound-emitting material of the cone suspension 4. A voice coil has been designated 7.

The coil 7 is kept floating in a magnetized air gap 8 in a manner known per se by means of a resilient guide disc 9. The main cone 1 consists of an oblique cone, the generator of which follows an elliptical curve, which forms the edge 6 of the sound-emitting membrane. on the edge 6 which are located furthest apart from each other have been designated 11 and 12. The major axis 13 connecting the points 11 and 12 constitutes the line which I, in the introduction, has been called the first reference line. Correspondingly, said second reference line forms a short axis 16 to the edge plane Q. 30, Ä É The main cone is, as already mentioned, oblique. More specifically, it is oblique in such a way that its tip, which coincides with the drive point 3, projected perpendicular to the plane determined by the boundary line 6, will impinge on both the major axis and the side axis. of the short axis 16, 35 in short in one of the four quadrants of the ellipse 6. According to the embodiment, the drive point 3 is so close to the edge 6 of the main cone 1 that the treble cone 2 á few; s .. V n ...- Ä¿ m 4 'ALL ¿_ 5 10 15 20 25 30 35, thin aluminum foil coated with cellulose on the front. Another _ within the frequency range 5-20 knz. To prevent distortion between see, 447 692; edge 17, projected on the edge plane of the main cone 1, is approximately tangent to the edge cone 6 of the main cone 2. The major axis 18 of the treble cone 2 is about half as long as the major axis 13 of the main cone 1, and the minor axis 19 of the treble cone is slightly less than half of the minor axis. according to the embodiment, the plane of the major axis 13 is 140 to 150 °.

The main cone 1 can be made of a variety, preferably rather rigid materials, such as cardboard, plastic, metal foil, coated fabric, etc. or of combinations of several materials. In one case, the cone 1 is made of suitable material is carbon fiber reinforced plastic, which on one or both sides is covered with different materials within zones D, M and B, which represent the approximate ranges for reproducing frequencies within the treble range (5-7 kHz), the intermediate frequency range (200 Hz - 5 kHz) and the base frequency range (75 Hz - 200 Hz), respectively. The treble cone 2, which may for instance consist of cardboard or thin aluminum foil, emits sound the treble cone 2 and the main cone 1, the zone D of the main cone 1 can be coated with a silicone layer on one or both sides, which has a damping effect on the sound reproduction. In zone M the cone 1 can be coated with a metal layer on one or both sides, and in the base zone B the cone can be coated with a cellulose layer on one or both sides (the layers not shown in the figures). The cone 1 can also be provided with holes 21, so that air can pass through, which acts as a mass relief from the cone 1, which when it pivots can be regarded as a body integrated with the nearest volume of air.

The speech coil 7 is connected to the main cone 1 and to the treble cone 2 by a tapered element 22 of non-magnetic material, for example aluminum. According to the embodiment, the element 22 has the shape of a cone. but other shapes are also conceivable, provided that the element results in a tip or rather in a concentrated area, which forms the common driving point 3 of the main cone 1 and the treble cone 2. The main cone 1 is folded to obtain greater rigidity. The fold has been designated 23. These folds 23 converge at the driving point 3. The total folds at this point have been designated 24. '447 692 The number coil 7 can be said to operate as a piston which transmits the oscillations via the connecting element g 22 to the main cone 1 and the treble cone 2. Since the drive point 3 is displaced far from the center of the device, if no compensating countermeasures were taken, oscillations 5 would be obtained predominantly in the treble cone 2 and in the upper left quadrant b of the main cones 1 with reference to Fig. 1. To stimulate oscillations even in bass § zone B, this is more flexibly suspended 1 the chassis 5 than the treble zone ¿D. This has been achieved in that the cone suspension 4 is substantially wider in the area furthest from the driving point 3 P 10 than in the area closest to it, as also shown of the figures. The diaphragm% in the base zone B can thus move significantly more easily than the diaphragm in the treble zone D. Furthermore, the center axis 25 of the voice coil 7 tilts towards the center of the device, i.e. in the same direction as the base zone B. which also promotes the driving of vibrations to the base zone B. 15 20 åt »lå å -l

Claims (10)

10 15 20 25 35 447 692 PATENT CLAIMS A device for loudspeakers comprising a drive means (7) for converting electrical oscillations into mechanical ones, which drive means is connected to at least one acoustic first diaphragm (1), so that its moving relay energy is propagated to the diaphragm and converted into sound energy, characterized that the edge (6) of the diaphragm (1) has an elongated round shape, and that the drive means (7) is connected to the diaphragm in a drive area (3), which is projected perpendicular to the edge plane of the diaphragm lying next to a first reference line (13), which connects the furthest points (11, 12) of the edge line and also next to a second reference line (16), which perpendicularly intersects the first: the reference line midway between said points, so that the two lines å (13, 16) divide the edge plane in four quadrants, one of which houses said drive area (3). ç fl w ¿, Ä Device according to claim 1, characterized in that the drive means (7) is attached to the diaphragm (1) via a non-magnetic portion (22), which tapers towards a tip, so that the transmission of oscillations to the diaphragm takes place in a drive point (3), which consists of a very concentrated area in the tip of the cone, and that the drive point and thus the contact surface between the diaphragm and the tapered portion connecting the voice coil to the diaphragm has a longest extent which does not exceed 10%, and preferably does not exceed % of the maximum extent of the msmbrane in the marginal plane. Device according to any one of claims 1-2, characterized in that the membrane has the main shape of an oblique cone (1), the cone angle of which in a plane coincides with the first reference line (13) is at least 130 °. Device according to one of Claims 1 to 3, characterized in that the membrane is stiffened by folds (23) extending from the drive point (3) to the edge (6). Device according to any one of claims 1-4, characterized in that a tweeter cone (2) is arranged inside the first-mentioned cone (1). which constitutes in v; -fr-ypw »447 692 the main cone of the loudspeaker, the treble cone being connected to the main cone in the drive point common to the cones (3). Device according to claim 5, characterized in that the edge of the tweeter cone projected perpendicular to the edge plane of the main cone extends substantially to or past the edge of the main cone (6). Device according to one of Claims 5 and 6, characterized in that the main cone in a zone (D) in the region closest to the drive point, which zone at least substantially corresponds to the extent of the treble cone (2), is made of a material which is substantially not capable of reproducing sound within the treble frequency range, but capable of transmitting the oscillations of the diaphragm (1) to the more distant parts of the diaphragm from the driving point. 15 Device according to claim 7, characterized in that the main cone (1) consists of different materials in at least the zones for treble frequency reproduction and base frequency reproduction and preferably also in a zone (H) for intermediate frequency reproduction. 20 Device according to any one of claims 5-8, characterized in that the main cone membrane is perforated. ; Device according to any one of claims 1-8, characterized in that the cantrum axis (25) of the number cone is inclined towards said edge plane in the direction), towards the parts (B) of the main cone which are furthest from the drive point (3) and / or that the cone suspension (4) is more flexible in the area furthest from the drive point than in the area close to it in order for the diaphragm of the main cone to become more easily movable in the former area fj 30 than in the latter. .; »M - Å 1. '». = - »J> .š>' 1-" 'I ~ g. \ I * 1 V -... L. _!