This application is a U.S. National Phase Application of PCT International Application PCT/JP2009/000193.
The present invention relates to speaker diaphragms and speakers using the speaker diaphragm.
A speaker diaphragm employed in a speaker requires a high Young's modulus and moderate internal loss in order to reproduce high-quality sounds from the speaker.
However, aforementioned conventional speaker diaphragm 204 is configured by simply attaching inorganic fiber fabric 201 and natural fiber nonwoven fabric 202, which have different natures. Therefore, inorganic fiber fabric 201 and natural fiber nonwoven fabric 202 are not sufficiently integrated. Accordingly, a high Young's modulus of inorganic fiber fabric 201 and high internal loss of natural fiber nonwoven fabric 202 are not fully demonstrated, failing to sufficiently improve the speaker sound quality.
The present invention improves the speaker sound quality by increasing Young's modulus and internal loss of a speaker diaphragm.
The speaker diaphragm of the present invention includes a fabric layer in which impregnated thermosetting resin is thermally cured, and a paper layer integrated on a rear face of this fabric layer. Fluffs of the paper layer filling stitches of the fabric layer are entangled with threads of the fabric layer from the surface of the fabric layer. The fabric layer and the paper layer are further integrated by thermosetting resin.
Furthermore, the speaker diaphragm of the present invention includes a fabric layer impregnated with thermosetting resin, and a nonwoven fabric layer that is pressure-bonded onto a rear face of this fabric layer by at least applying heat. Bamboo fiber is mixed in the non-woven fabric layer.
With the above structures, the present invention improves the speaker sound quality by increasing Young's modulus and internal loss of the speaker diaphragm.
Structures of exemplary embodiments of the present invention are described below with reference to drawings.
Paper layer 7 is formed by mixing aramid fiber with cellulose fiber, and is integrated on the rear face of fabric layer 6 by thermocompression bonding. Since paper layer 7 is integrated on the rear face of fabric layer 6 by thermocompression-bonding, as described above, air does not pass through from the surface to the rear face of speaker diaphragm 5. In addition, pulp configuring this paper layer 7 fills each stitch 10 surrounded by adjacent warp 8a and weft 8b of fabric layer 6.
An inner circumference of plate-like speaker diaphragm 5 is connected to a portion outside magnetic gap 13 of this voice coil 16. An outer circumference of this speaker diaphragm 5 is connected to an inner circumference of first edge 18, which has ring-like cross section, held at an upper opening of bowl-like frame 17. Dome-like dust cap 19 is provided near the inner circumference of this speaker diaphragm 5, so as to cover the top face of voice coil 16. This dust cap 19 prevents entry of dust or moisture into magnetic gap 13.
Leader line 20 from coil 15 of voice coil 16 is led out from this voice coil 16 between a portion, where speaker diaphragm 5 is connected, and a portion inside magnetic gap 13 to frame 17 without making contact with speaker diaphragm 5.
An inner circumference end of resilient second edge 21, which has a ring-like cross section, is connected to this voice coil 16 via suspension holder 21a at a portion between a lead-out point of leader line 20 and a portion inside magnetic gap 13. The other end of this second edge 21 is connected to an inner middle portion of frame 17.
These second edge 21 and first edge 18 are formed of a resilient material such as urethane or rubber. These edges have shapes protruding in opposite directions: second edge 21 protruding downward, and first edge 18 protruding upward.
The shapes of first edge 18 and second edge 21 protruding in opposite directions to each other make upward and downward movable loads of voice coil 16 approximately balanced.
Accordingly, operation of speaker diaphragm 5 also becomes vertically symmetric. As a result, distortion in the sound reproduced from speaker 12 can be reduced.
When audio signal travels in voice coil 16 of speaker 12 as configured above, the audio signal reacts with a magnetic field formed by magnetic gap 13, and a drive force is generated in voice coil 16. This driving direction follows the Fleming's left-hand rule, and voice coil 16 fluctuates vertically. By fluctuation of this voice coil 16, speaker diaphragm 5, whose inner circumference is connected to voice coil, also vertically vibrates. This vibrates air, and the sound is generated from speaker 12.
However, if a speaker diaphragm is formed by overlaying materials with different natures, such as fabric and paper, integration of these materials have not been feasible. As a result, it is difficult to demonstrate the maximum effect of high Young's modulus of the fabric layer and high internal loss of the paper layer, which are firmly fixed by thermosetting resin, in the speaker diaphragm of this structure. Accordingly, the sound quality of speaker has not been sufficiently improved.
Therefore, in speaker diaphragm 5 in the first exemplary embodiment, pulp fluff 7a of paper layer 7 filling stitch 10 of fabric layer 6 entangles with thread 9 of fabric layer 6 on the surface of fabric layer 6, and is firmly fixed by thermosetting resin.
By the use of speaker diaphragm 5 adopting the structure that pulp fluff 7a fills stitch 10 of fabric layer 6 and is entangled with thread 9 from the surface of fabric layer 6, the sound quality of speaker 12 can be improved.
This is because, firstly, a larger portion of pulp, which has high internal loss, is filled in stitches 10 of fabric layer 6 in speaker diaphragm 5, compared with conventional speaker diaphragm 204 shown in
Furthermore, in speaker diaphragm 5, a two-layer structure of paper layer 7 formed by fine linear fibers and fabric layer 6 enables fiber fluffs 7a of paper layer 7 to enter stitches 10, and allows fluffs 7a to entangle with warps 8a and wefts 8b of fabric layer 6 from the surface of fabric layer 6. Accordingly, unlike conventional speaker diaphragm 204 with a general structure that only the rear face of fabric layer 6 is attached to paper layer 7, fabric layer 6 and paper layer 7 are integrated. As a result, speaker diaphragm 5 is strengthened, and achieves high Young's modulus, compared to that of conventional speaker diaphragm 204, improving the sound quality.
As described above, speaker diaphragm 5 in the first exemplary embodiment of the present invention improves the sound quality of speaker 12 by increasing internal loss and Young's modulus. In addition, as described above, fabric layer 6 and paper layer 7 are firmly integrated in speaker diaphragm 5. This also significantly reduces a chance of separation of fabric layer 6 and paper layer 7.
Thermosetting resin contained in fabric layer 6 is preferably resin at least containing one of phenol resin, acrylic resin, epoxy resin, and vinylester resin. Any resin containing one of these resins fully cures at thermocompression bonding, and increases hardness of speaker diaphragm 5. This can increase Young's modulus of speaker diaphragm 5.
Aramid fiber may be mixed in paper layer 7. By mixing aramid fiber, which is hard, in paper layer 7, speaker diaphragm 5 can be strengthened, accompanied by increased hardness of speaker diaphragm 5. Accordingly, Young's modulus can be further increased. If aramid fiber is used for fabric layer 6, in addition to mixing of aramid fiber in paper layer 7, entire speaker diaphragm becomes configured with aramid fiber. This can further increase Young's modulus.
In the same way, fabric layer 6 is preferably a fabric containing at least one of hard fibers, such as aramid fiber, polyester fiber, acrylic fiber, cotton fiber, carbon fiber, glass fiber, and silk fiber. The use of a fabric containing these fibers improves hardness of fabric layer 6, and thus Young's modulus of speaker diaphragm 5 can be increased.
Next is described a method of manufacturing speaker diaphragm 5 in the first exemplary embodiment of the present invention.
In
At this point, pulp sedimentary layer 25 and flat fabric 26 are deformed by pressure and compression, and become shapes of paper layer 7 and fabric layer 6 of speaker diaphragm 5 shown in
Furthermore, first mold 22 and second mold 23 are heated at temperatures between 180° C. and 250° C. in a state that pulp sedimentary layer 25 and flat fabric 26 are clamped, so as to integrate pulp sedimentary layer 25 and flat fabric 26 by thermally curing thermosetting rein in flat fabric 26. Then, first mold 22 and second mold 23 are opened, formed speaker diaphragm 5 is taken out, and papermaking screen 24 is peeled off. In the first exemplary embodiment of the present invention, the molds are clamped in the state that pulp sedimentary layer 25 and papermaking screen 24 are placed on second mold 23. However, papermaking screen 24 may be peeled off after heating and drying pulp sedimentary layer 25, and only flat fabric 26 and pulp sedimentary layer 25 may be clamped.
Speaker diaphragm 5 in the first exemplary embodiment is formed through the above processes.
In the method of manufacturing the speaker diaphragm in the first exemplary embodiment of the present invention, fluffs 25a in pulp sedimentary layer 25 on the face opposing first mold 22 are filled in stitches of flat fabric 26, and compression molding can be achieved in the state that fluffs are protruding from the surface of flat fabric 26. Accordingly, speaker diaphragm 5 can be achieved with the structure that fluffs become entangled with threads 9 from the surface of fabric layer 6, as shown in
After drying pulp sedimentary layer 25, pulp sedimentary layer 25 may be further fluffed by giving a brushing using a wire brush or coarse sandpaper. Further fluffed pulp sedimentary layer 25 enables further more fluffs to enter stitches of flat fabric 26, and thus filling rate of fluffs 7a of paper layer 7 in stitches 10 can be increased in the manufacture of speaker diaphragm 5. In addition, more fluffs 7a of paper layer 7 become entangled with threads 9.
Furthermore, to make pulp sedimentary layer 25 more fluffy, fibers having a fibrillar structure including animal fiber such as wool, bast fiber such as hemp, or seed-pod fibers such as cotton and Kapok may be mixed in pulp that becomes a raw material of paper layer 7. More specifically, if fibers with a structure of bundled fine fiber elements, such as the fibrillar structure, are mixed, pulp sedimentary layer 25 becomes further fluffy because these fibers split at drying. Accordingly, more fluffs 25a can enter stitches of flat fabric 26. Furthermore, the layer can be further fluffed by giving a brushing using a wire brush or coarse sandpaper to pulp in which fiber with the fibrillar structure is mixed.
This fabric layer 102 contains at least one of high-strength fiber such as aramid fiber, polyester fiber, acrylic fiber, cotton fiber, carbon fiber, glass fiber, and silk fiber. Thermosetting resin is resin containing at least one of phenol resin, acrylic resin, epoxy resin, and vinylester resin.
Nonwoven fabric layer 103 is formed by mixing bamboo fiber in softwood pulp fiber at content of 0.5 wt % to 20 wt %. The bamboo fiber mixed in this nonwoven fabric layer 103 is broken down to small freeness up to the microfibrillar state. Its average fiber diameter is 5 μm or less, which enables sufficient entanglement with softwood pulp fiber.
Nonwoven fabric layer 103 is integrated on the rear face of fabric layer 102 by thermocompression-bonding. Since nonwoven fabric layer 103 is integrated on the rear face of fabric layer 102 by thermocompression-bonding, air does not pass through from the surface to the rear face of speaker diaphragm 101.
Furthermore, the bamboo fiber and softwood pulp fiber configuring this nonwoven fabric layer 103 fill each stitch 108 surrounded by adjacent warp 105 and weft 106 of fabric layer 102.
An inner circumference of conic speaker diaphragm 101 is connected to an outer circumference near the upper end of this voice coil 115. The outer circumference of this speaker diaphragm 101 is connected to bowl-like frame 117 at an opening on the top face via ring-like first edge 116. Dome-like dust cap 118 is provided near the inner circumference of this speaker diaphragm 101 so as to cover the top face of voice coil 115. This dust cap 118 prevents entry of dust or moisture into magnetic gap 112.
Leader line 119 from coil 114 of voice coil 115 is led out from an upper part of this voice coil 115 to outside frame 117 without making contact with speaker diaphragm 101. An AC current, in which an audio signal is added, travels from outside the speaker to coil 114 via this leader line 119.
An inner circumference end of resilient second edge 120, which has a ring-like planar shape, is connected to this voice coil 115 via suspension holder 121 at a portion between a lead-out point of leader line 119 and a portion inside magnetic gap 112. The other end of this second edge 120 is connected to an inner middle portion of frame 117.
These second edge 120 and first edge 116 are formed of a resilient material such as urethane or rubber. These edges have shapes protruding in opposite directions: second edge 120 protruding downward and first edge 116 protruding upward.
The shapes of first edge 116 and second edge 120 protruding in opposite directions to each other make upward and downward movable loads of voice coil 115 approximately balanced.
Accordingly, vertical operation of speaker diaphragm 101 also becomes vertically symmetric. As a result, distortion in the sound reproduced from speaker 111 can be reduced.
When audio signal travels in voice coil 115 of speaker 111 as configured above, the audio signal reacts with a magnetic field formed by magnetic gap 112, and a drive force is generated in voice coil 115. This driving direction follows the Fleming's left-hand rule, and voice coil 115 fluctuates vertically. By fluctuation of this voice coil 115, speaker diaphragm 101, whose inner circumference is connected to voice coil 115, also vertically vibrates. This vibrates air, and the sound is generated from speaker 111.
However, when a speaker diaphragm is formed by overlaying materials such as fabric and paper, they cannot be fully integrated because of their different natures. As a result, it is difficult to demonstrate the maximum effect of high Young's modulus of the fabric layer and high internal loss of the nonwoven fabric layer, which are firmly fixed by thermosetting resin, in the speaker diaphragm configured in this way. Accordingly, the sound quality of speaker has not been sufficiently improved.
Therefore, speaker diaphragm 101 in the second exemplary embodiment has a structure of mixing bamboo fiber in nonwoven fabric layer 103.
In nonwoven fabric layer 103, in which the bamboo fiber is mixed, the bamboo fiber likely rises against the surface of nonwoven fabric layer 103 because of its highly rigid and strong characteristic. Therefore, many fluffs 104 of bamboo fiber rise against the surface of nonwoven fabric layer 103, and these fluffs 104 fill stitches 108 of woven fabric layer 102. Since fluffs 104 are filled in stitches 108 of woven fabric layer 102, and two layers are thermocompression-bonded and integrated by thermosetting resin in a state fluffs 104 are entangled with threads 107 of fabric layer 102, fabric layer 102 and nonwoven fabric layer 103 are firmly integrated.
Accordingly, fabric layer 102 and nonwoven fabric layer 103 are sufficiently integrated in speaker diaphragm 101 in the second exemplary embodiment of the present invention, compared to conventional speaker diaphragm 204 (see
In addition, since the bamboo fiber has high rigidity and strength, Young's modulus of speaker diaphragm 101 is further increased by this rigidity and strength of the bamboo fiber.
As described above, speaker diaphragm 101 in the second exemplary embodiment of the present invention can increase internal loss and Young's modulus, and thus the sound quality of speaker 111 can be improved. In addition, as described above, fabric layer 102 and nonwoven fabric layer 103 are firmly integrated in speaker diaphragm 101 in the second exemplary embodiment of the present invention. This also significantly reduces a chance of separation of fabric layer 102 and nonwoven fabric layer 103.
Speaker diaphragm 101 in the second exemplary embodiment of the present invention that uses the bamboo fiber as a material mixed in nonwoven fabric layer 103 also excels in cost and environmental aspects. More specifically, softwood that has been used as a material for the conventional speaker diaphragm is cut down worldwide for various purposes other than for speaker diaphragms. Therefore, softwood shortages are in concern at present. On the other hand, bamboos exist more, centering on Asia, compared to softwood. In addition, extremely high growth speed of bamboo is assumed to give no detrimental effect on environment like the case of cutting softwood. Under these circumstances, the bamboo fiber is mixed in nonwoven fabric layer 103 in the second exemplary embodiment of the present invention to reduce the percentage of softwood pulp fiber in nonwoven fabric layer 103. As a result, speaker diaphragm 101 in the second exemplary embodiment of the present invention can be manufactured at low cost without giving a detrimental effect on environment.
Still more, in the second exemplary embodiment of the present invention, the bamboo fiber mixed in nonwoven fabric layer 103 is broken down to the microfibrillar state whose average fiber diameter is 5 μm or less. By mixing bamboo fiber broken down to the microfibrillar state, the bamboo fiber and softwood pulp fiber can be further entangled. This improves Young's modulus of the speaker diaphragm.
In the second exemplary embodiment, the average fiber diameter of the bamboo fiber mixed in nonwoven fabric layer 103 is 5 μm or less. However, the average fiber diameter of bamboo fiber may also be 5 μm or more. The use of bamboo fiber with average fiber diameter of 5 μm or more may have less strength in entanglement of the bamboo fiber and softwood pulp fiber, but it still shows sufficiently high Young's modulus and internal loss, compared to that of the conventional diaphragm. Furthermore, nonwoven fabric layer 103 may be configured only with the bamboo fiber to form speaker diaphragm 101. In this case, original nature of bamboo fiber, i.e., rigidity and strength, is demonstrated, and high Young's modulus can be achieved compared to that of the conventional speaker diaphragm.
Thermosetting resin contained in fabric layer 102 is preferably resin at least containing one of phenol resin, acrylic resin, epoxy resin, and vinylester resin. Any resin containing one of these resins fully cures at thermocompression-bonding and increases hardness of speaker diaphragm 101. This can increase Young's modulus of speaker diaphragm 101.
Aramid fiber may be mixed in nonwoven fabric layer 103. By mixing aramid fiber, which is hard, in nonwoven fabric layer 103, speaker diaphragm 101 can be strengthened, accompanied by increased hardness of speaker diaphragm 101. Accordingly, Young's modulus can be further increased. Also in the case of mixing aramid fiber, as described above, the bamboo fiber can be sufficiently entangled with aramid fiber by breaking down the bamboo fiber to the microfibrillar state. The characteristic of bamboo fiber can thus be demonstrated.
In the same way, fabric layer 102 is preferably a fabric containing at least one of hard fibers, such as aramid fiber, polyester fiber, acrylic fiber, cotton fiber, carbon fiber, glass fiber, and silk fiber. The use of fabric containing these fibers improves hardness of fabric layer 102, and thus Young's modulus of speaker diaphragm can be increased.
In a speaker employing this speaker diaphragm 101, a reticular pattern of fabric layer 102 is preferably exposed on the speaker surface.
In other words, generation of local resonance in speaker diaphragm can be prevented by adopting a structure that the reticular pattern woven by warps 105 and wefts 106, as shown in
Next is described a method of manufacturing speaker diaphragm 101 in the second exemplary embodiment of the present invention.
Second mold 123 has a bowl-like shape that fits with the conic trapezoidal shape of this first mold 122. A heater for heating (not illustrated) is attached to these first mold 122 and second mold 123.
In
In this state, the heater of second mold 123 is driven to heat and evaporate moisture in sedimentary layer 125. Since first mold 122 is not pressed downward at this point, sedimentary layer 125 is not compressed between first mold 122 and second mold 123. In other words, sedimentary layer 125 is heated and dried without applying pressure. In the second exemplary embodiment of the present invention, only the heater attached to second mold 123 is driven. However, a heater attached to first mold 122 may also be driven at the same time, in addition to the heater embedded in second mold 123. Alternatively, sedimentary layer 125 may be dried by hot air typically of a drier, or may be left to natural drying without driving the heaters.
In particular, fluffs 125a of bamboo fibers rise against the surface of sedimentary layer 125, compared to softwood pulp fibers. This is because bamboo fibers tend to retain their state before drying due to its high rigidity and strength, compared to softwood pulp fiber, while dried softwood pulp fibers tend to lie on the surface of sedimentary layer 125 and align along the surface of sedimentary layer 125 (a state that they lie on the surface). More specifically, bamboo fibers oriented to directions other than the direction along the surface of sedimentary layer 125 before drying retain their positions at heating and drying. As a result, these bamboo fibers rise against the surface of sedimentary layer 125 after drying.
In other words, in randomly-oriented bamboo fibers in sedimentary layer 125 before drying, bamboo fibers exist on the surface of sedimentary layer 125 and are not aligned along the surface of sedimentary layer 125 become fluffs 125a.
At this point, sedimentary layer 125 and flat fabric 126 are deformed by pressure and compression, and become shapes of nonwoven fabric layer 103 and woven fabric layer 102 of speaker diaphragm 101 shown in
Furthermore, first mold 122 and second mold 123 are heated at temperatures between 180° C. to 250° C. in a state that sedimentary layer 125 and flat fabric 126 are clamped so as to integrate sedimentary layer 125 and flat fabric 126 by thermally curing thermosetting resin in flat fabric 126. In other words, sedimentary layer 125 and flat fabric 126 are integrated by applying heat, and they are also integrated by fluffs 125a entangled with flat fabric 126.
Then, first mold 122 and second mold 123 are opened, formed speaker diaphragm is taken out, and papermaking screen 124 is peeled off. In the second exemplary embodiment of the present invention, the molds are clamped in the state that sedimentary layer 125 and papermaking screen 124 are placed on second mold 123. However, papermaking screen 124 may be peeled off after heating and drying sedimentary layer 125, and only flat fabric 125 and sedimentary layer 125 may be clamped.
Speaker diaphragm 101 in the second exemplary embodiment is formed by cutting unnecessary portions after the above processes.
In the method of manufacturing the speaker diaphragm in the second exemplary embodiment of the present invention, fluffs 125a in sedimentary layer 125 on the face opposing first mold 122 are filled in stitches of flat fabric 126, and compression-molding can be achieved in the state that fluffs 125a are protruding from the surface of flat fabric 126. Accordingly, speaker diaphragm 101 can be achieved with the structure that fluffs 104 become entangled with threads 107 from the surface of fabric layer 102, as shown in
The speaker diaphragm of the present invention has a structure that the paper layer and fabric layer are integrated by firmly fixing these layers by thermosetting resin while fluffs of the paper layer are entangled with threads from the surface of the fabric layer. This can increase internal loss and Young's modulus of the speaker diaphragm.
Furthermore, the speaker diaphragm of the present invention has the structure that bamboo fibers are mixed in the nonwoven fabric layer. Fluffs of bamboo fibers, in addition to fluffs of the nonwoven fabric layer, are filled in stitches of the fabric layer, and these fluffs are entangled with threads from the surface of the fabric layer. This firmly integrates the woven fabric layer and nonwoven fabric layer, increasing internal loss and Young's modulus of the speaker diaphragm.
Accordingly, the speaker diaphragm of the present invention can improve the speaker sound quality, and is thus effectively applicable to a range of audio equipment.
Number | Date | Country | Kind |
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2008-011252 | Jan 2008 | JP | national |
2008-082796 | Mar 2008 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2009/000193 | 1/21/2009 | WO | 00 | 7/21/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/093444 | 7/30/2009 | WO | A |
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