NO140846B - HOW SPEAKERS. - Google Patents

Description

The invention relates to a loudspeaker comprising a diaphragm with a voice coil, a frame surrounding the diaphragm and a suspension device for suspending the diaphragm in the frame.

In a typical conventional dynamic speaker there is a circular yoke, an annular yoke, an annular magnet and a central pole attached to the circular yoke. The vibration system comprises a cylindrical coil form, a voice coil or voice coil wound around the cylindrical coil form, a suspension device or a damper for suspending the coil form in a cone-shaped frame, and a cone-shaped membrane that is fixed with an adhesive on the upper end of the coil form. The outer edge of an annular suspension device is attached to the upper end of the frame with a suitable adhesive and the inner edge of the device is attached to the upper end of the membrane by means of a suitable adhesive.

In general, the suspension device provides an edge for the cone which has a curved portion with an approximately semi-circular cross-section projecting upwards at its center and which is elastically deformable due to its own elasticity, so that the membrane can be vibrated linearly in a vertical direction. The stiffness of the edge has an important effect on the lower frequency characteristic. The stiffness should be reduced to lower the lower threshold frequency. For this purpose, the edge is usually formed of urethane sponge or cotton cloth impregnated with phenolic resin, or of a mixture of nitrile butadiene rubber, styrene butadiene rubber or isobutyl isoprene rubber with carbonaceous fine grains.

In order to achieve satisfactory vibration of the membrane, it is necessary that the edge is deformable both radially and circumferentially. Furthermore, it is necessary that the circumferential deformation is greater than the radial deformation.

An edge or fold formed from cotton fabric has the following disadvantages: When the membrane is vibrated strongly, the edge wrinkles and its internal loss is increased as it is slightly deformed in the circumferential direction. Otherwise, tones are generated from the edge.

An edge formed from the vulcanized mixture of the above-mentioned rubber type with carbonaceous fine grains has the following disadvantages: The thickness of the edge should be relatively large in order to achieve the necessary stiffness. Therefore, the sound conversion efficiency decreases with increasing edge weight.

Generally, the damper is ring-shaped and has a wavy appearance, and is deformable in the radial direction. This prevents the swing coil from coming into contact with the yoke during vibration. It under-supports the diaphragm and the voice coil.

The stiffness of the damper also has an important effect on the lower threshold frequency f. With a damper that has a large degree of stiffness, sounds cannot be reproduced with high reproduction accuracy, as the damper does not vibrate accompanied by the membrane. For this reason, the damper is manufactured in such a way that the cotton cloth impregnated with phenolic resin is formed into a wave shape under heat so that a lower stiffness is achieved.

However, a conventional damper cannot be deformed in the circumferential direction when the vibration system is in operation. Consequently, the linearity of the deformability is unsatisfactory under large vibrations. The size and thickness of the damper is increased to achieve the necessary stiffness, and thus the damper's weight is also increased. Consequently, the internal losses in the damper are reduced. Therefore, the speaker's mechanical impedance increases in the lower frequency range. As a result of this, the sharpness of the mechanical resonance and the electrical resonance is increased and thus the quality of the reproduced sounds is degraded.

An object of the invention is to provide a loudspeaker with good frequency response characteristics.

Another object of the invention is to provide a loudspeaker with a light suspension device which has a high degree of stiffness, and which is deformable in a circumferential direction at its lower end, and where the sharpness of mechanical and electrical resonances is therefore reduced.

The above-mentioned purpose is achieved by a loudspeaker of the kind indicated at the outset, which according to the invention is characterized by the fact that the suspension device is formed from a mixture of an elastic material and carbon fibres.

A preferred embodiment of the invention is characterized by the fact that the elastic material is rubber and that the carbon fibers are needle-like and are radially arranged in the suspension device. With such an orientation of the carbon fibers, the deformability in the circumferential direction is improved and the suspension device is prevented from wrinkling.

With the help of the suspension device according to the invention, a good sound characteristic is achieved as signals can be transformed into sounds with high reproduction accuracy in the higher frequency ranges, and vibrations can be dampened sufficiently in lower frequency ranges.

The invention shall be described in more detail below

in connection with a number of illustrative embodiment examples with reference to the drawings, where fig. 1 shows a schematic cross-sectional view of a loudspeaker according to a preferred embodiment of the invention, fig. 2 shows a plan view of a first embodiment of a suspension device in the loudspeaker according to fig. 1, fig. 3 shows an enlarged plan view of part of the first suspension device according to fig. 2, fig. 4 shows a cross-sectional view along the line IV - IV in fig. 3, and fig. 5 shows a cross-sectional view of a metal mold that is used for the production of the suspension device according to fig. 2; fig. 6 shows a plan view of a second embodiment of a suspension device in the loudspeaker according to fig. 1, fig. 7 shows an enlarged plan view of part of the suspension device in fig. 6, fig. 8 shows a cross-sectional view along the line VIII - VIII in fig. 7, fig. 9 is a diagram showing a frequency response characteristic, and FIG. 10 is a diagram showing a frequency-impedance characteristic.

In fig. 1 shows the magnet part of a loudspeaker 1 according to an embodiment of the invention which comprises a circular yoke 2a, an annular yoke 2b, an annular magnet 3 which is placed between the circular yoke 2a and the annular yoke 2b, and a central pole 4 which projects upwards from the center of the circular yoke 2a and is

attached to this. A vibration system comprises a coil form 5

for a voice coil, a voice coil 6 which is wound around the coil form 5, and a cone-shaped membrane 9 which is attached to the upper end of the coil form 5. A first ring-shaped suspension device 20 is attached to the upper end of a frame by means of a suitable binder 7 and to the upper end of the membrane 9. A second annular suspension device, namely a damper 28, is attached to the lower end of the membrane 9 for elastic suspension of the membrane in the frame 7. A sound absorber or silencer 11 is attached to the upper surface of the coil form 5. A cover 12 covers the surface of the muffler 11. A clamping ring 13 is attached to the upper end of the suspension device or edge 20 to prevent the edge from peeling off from the upper end of the frame 7.

The first suspension device or edge 20 will now be described in detail with reference to fig. 2-4.

The first suspension device 20 comprises an upwardly projecting, curved or ridge-shaped part 20a with an approximately semicircular cross-section, an inclined part 20b and an outer horizontal, circumferential part 20c. The first suspension device 20 is produced in such a way that carbon fibers 21 with lengths of from 0.3

to 0.8 mm is mixed into elastic material, such as synthetic rubber (e.g. nitrile butadiene rubber, styrene butadiene rubber and isobutyl isoprene rubber), natural rubber or synthetic resin (e.g. soft foam urethane). The carbon fibers 21 are aligned radially as schematically shown in fig. 3.

The upper end of the membrane 9 is attached to the inclined part 20b of the first suspension device 20, and the upper end of the frame 7 is attached to the horizontal, circumferential part 20c of the suspension device.

The method for producing the edge 20 will be described

in the following with reference to fig. 5.

1 to 40% carbon fibers with a Young's modulus of 20,000 kg/mm, a diameter of 8 ym and a length of from 3 to 6 mm, and a different material, such as e.g. stearic acid, sulphur, carbon black etc., are mixed into solid styrene butadiene rubber using a mixing mill where the carbon fibers are cut needle-like to 0.3 to 0.8 mm. A resulting mixture 22 is placed in the center of a metal mold 23 which is heated to a required temperature, e.g. 150°C, and which delimits an annular groove 24 with the same cross-section as the first suspension device 20. Furthermore, another metal mold 26 is arranged with a corresponding, annular projection 25 with the same cross-sectional shape as the annular groove 24. The metal mold 26 is placed over the heated metal mold 23 to the mentioned temperature. The mixture 22 is placed between the metal molds 23 and 26. When the metal mold 26 is pressed down, the mixture 22 is consequently spread outwards radially from the center. the metal form 2 3 in the direction shown by the arrows 27 in fig. 5, and is then introduced into the annular groove 24 between the metal forms 23 and 26.

When the annular projection 25 is fitted into the annular

track 24, the mixture 22 is vulcanized at a temperature of above

140°C between the metal molds 23 and 26. The metal molds 23 and 26 are then cooled so that the mixture 22 solidifies. The formed mixture 22 is extracted from the metal mold 23. As a result, the first suspension device 20 is obtained, as shown in fig.

2 and 4.

As the mixture 22 is spread out directionally during the manufacturing process, the carbon fibers 21 in the mixture 22 are displaced accordingly. Carbon fibers 21 with lengths of from 0.3 to 0.8 mm are therefore radially distributed in the diameter direction of the first suspension device 20 (Fig. 3 ).

With such a spread of the carbon fibers 21, the deformability of the first suspension device 20 is improved in the circumferential direction. There is no possibility of the first suspension device being wrinkled. The specific weight of the first suspension device 20 is small and the stiffness of the device is great as it is produced in a vulcanization process of the mixture containing carbon fibres. The thickness of the curved part 20a of the first suspension device 20 can consequently be reduced to the minimum to achieve the necessary rigidity, and thus the total weight of the first suspension device 20 can be reduced.

According to the invention, the second suspension device 28 is also produced from a mixture of elastic material and carbon fibres.

In fig. 6 - 8, the second suspension device 28 is shown to comprise a number of concentric, curved parts 28a with an upwardly projecting, semicircular cross-section. The device also comprises concentric, curved parts 28b with a downward-extending, semi-circular cross-section, an inner, downward-extending edge part 28c with a U-shaped cross-section and a horizontal, circumferential part 28d. The second suspension device 28 is formed from a mixture of the same elastic material as the first suspension device 20, and contains carbon fibres. As shown in fig. 7, carbon fibers 31 with lengths of from 0.3 to 0.8 mm are radially aligned in the diameter direction of the second suspension device 28. It is preferred that the carbon fibers 31 have a Young's modulus greater than 20,000 kg/mm 2 and that the diameter of the carbon fibers is less than the length of the carbon fibers, e.g. about. 8 etc. 1 to 40% carbon fibers 31 are contained in the second suspension device 28.

In the speaker 1, the inner end part 28c is attached to the coil form 5, and the horizontal, peripheral part 28d is attached to the frame 7. The second suspension device 28 can be manufactured in the same way as the first suspension device 20.

The deformability of the second suspension device 28 is higher in the circumferential direction than in the radial direction as the carbon fibers 31 are spread out radially in the suspension device. When a mixture of styrene butadiene rubber with carbon fibers is vulcanized to produce the second suspension device 28, a low specific weight and high rigidity of the suspension device can be achieved. The thickness of the suspension device 28 can consequently be reduced to a minimum for the required rigidity, and thus the total weight of the suspension device can be reduced.

Fig. 9 shows the frequency response characteristic for dynamic speakers of the cone type using the first suspension device 20 according to the invention, and the conventional first suspension device which is made of cotton cloth.

In a curve "a" for a speaker using cotton fabric, the response fluctuates for frequencies above 500 Hz, where peaks or troughs appear. The quality of the tone is therefore degraded. In a curve "b" for a speaker using the first suspension device according to the invention, no peaks or troughs occur for higher frequencies. The response decreases sharply for frequencies above an upper threshold frequency of 1500 Hz. A high tone quality can therefore be achieved. The reason for this is that the suspension device according to the invention does not wrinkle when vibrated and no sound is generated from the suspension device, and that the sound conversion efficiency is improved due to the weight reduction.

Fig. 10 shows the frequency-impedance characteristic. Curve "a" applies to a conventional speaker that uses a damper formed from cotton cloth impregnated with phenolic resin, where the resonant frequency f o is 78 Hz, the maximum impedance Z o is 100 n and the minimum impedance R£ is 6 Q . The sharpness QM for the mechanical resonance is represented by the equation

where f^ and f~ are frequencies for an impedance From curve "a" the frequencies f^ = 67 Hz and f2 = 88 Hz appear. Therefore, the curve becomes "a". The sharpness QQ of the electrical resonance is represented by the equation

for curve "b".

The values of QM and are large for the conventional damper, as described above, and the damping effect is thus low for the lower frequency range. It will therefore be realized that the tone quality is inferior.

The frequency characteristic is noticeably improved by using the second suspension device 28 according to the invention, as shown by the curve "b" in fig. 10, where the resonance frequency f o is 84 Hz, the maximum impedance Z o is 24 Q and the minimum impedance RE is 6 fi. The frequencies and f2 are 50 Hz for an impedance

The sharpness QM for the mechanical resonance is therefore and the sharpness Qg for the electrical resonance is

It will be realized that QM and QQ can be significantly lowered

by means of the second suspension device according to the invention, compared to the conventional suspension device.

Although illustrative embodiments of the invention

has been described above with reference to the drawings, it will be understood that the invention is not limited to these embodiments, and that various changes and modifications can be made without going outside the scope of the invention.

For example the shape and size of the first and second suspension devices can be varied. Furthermore, the invention can also be applied to a speaker of the double cone type or a speaker of the dome type.

Claims (5)

1. Loudspeaker comprising a diaphragm with a voice coil, a frame surrounding the membrane and a suspension device for suspending the membrane in the frame, characterized in that the suspension device is formed from a mixture of an elastic material and carbon fibres. 2. Loudspeaker according to claim 1, characterized in that the elastic material is rubber and that the carbon fibers are needle-like and are radially arranged in the suspension device. 3. Loudspeaker according to claim 1 or 2, characterized in that the suspension device is placed between an upper part of the membrane and said frame and comprises an intermediate part with an arc-shaped cross-section. 4. Loudspeaker according to claim 1 or 2, characterized in that the suspension device is placed between a lower part of the membrane and said frame, and comprises an intermediate part with a wave-shaped cross-section. 5. Loudspeaker according to one of claims 1-4, characterized in that the elastic material is a plastic resin.