JP2002199488A - Diaphragm for loudspeaker - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a diaphragm for loudspeaker that is applicable to applications, especially those requiring high water resistance and water-repelling performance for loudspeakers for doors of automobiles or the like with high productivity, and can eliminate the need for a special pre-processings which have been required for the use of the conventional plastic-made diaphragm for loudspeaker in assembling of the loudspeaker. SOLUTION: The diaphragm for loudspeaker contains a base material made of natural fibers, chemical fibers or their mixture and containing a fluorochlorohydrocarbon derivative.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a diaphragm technology for a speaker.

[0002]

2. Description of the Related Art FIG. 4 is a cross-sectional view of a model of an example of a general electrodynamic speaker. A columnar pole piece 2 is attached to the center of a disk-shaped back plate 1. An annular magnet 3 is mounted on the periphery of the back plate 1 coaxially with the pole piece 2, and an annular plate 4 is mounted on the magnet 3 coaxially with the pole piece 2. Is formed.

In the magnetic gap, a cylindrical voice coil bobbin 6 provided with a voice coil 5 formed by winding an electric wire of a predetermined length is moved forward and backward in the axial direction (vertical direction in the figure) by a damper 7. It is movably held. The front of the voice coil bobbin 6 is connected to the central portion of the cone-shaped diaphragm 8, and the voice coil bobbin 6
A center cap 9 is mounted on the front opening.

The outer peripheral edge of the cone-shaped diaphragm 8 has an edge 10
Through the frame 11 fixed to the plate
Supported by The outer edge of the edge 10 is a frame 11, a diaphragm 8, a center cap 9, and a boss coil bobbin 6 formed by a gasket 12, which are vibrators. In order to faithfully convert the driving force generated by the input signal of the voice coil 5, these vibrators move back and forth integrally with the signal in the reproduction frequency band, and generate unnecessary peaks. It is required that reproduction with smooth sound pressure frequency characteristics can be performed without any problem.

[0005] Applications of such a speaker include in-vehicle applications such as automobiles. However, among these in-vehicle applications, when mounted for doors, waterproof parts are required for the parts that come into contact with the outside air, especially for the diaphragm, from the viewpoint of maintaining reliability and performance. In response to such demands, plastic diaphragms, especially polypropylene diaphragms, have begun to be widely used for the cone-shaped diaphragm and the center cap, particularly in terms of sound quality and frequency characteristics.

[0006] However, polypropylene has poor adhesiveness, requires time and labor to use a special agent or device such as a primer treatment or a corona discharge treatment, and requires a costly treatment. Therefore, when such a polypropylene-made cone-shaped diaphragm is used, there are problems such as an increase in manufacturing cost and poor mass productivity.

[0007]

The present invention solves the above-mentioned conventional problems, that is, it can be used for applications having particularly high water resistance and water repellency, such as speakers for automobile doors, and the productivity is improved. It is another object of the present invention to provide a speaker diaphragm which does not require pre-processing, which is required when a conventional plastic speaker diaphragm is used even during speaker assembly.

[0008]

According to a first aspect of the present invention, there is provided a loudspeaker diaphragm made of a natural fiber, a chemical fiber or a mixture of these fibers. And a speaker diaphragm containing a fluorochloro-substituted derivative of a hydrocarbon.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In the speaker diaphragm of the present invention, the fibers constituting the diaphragm base material are selected from natural fibers and chemical fibers usually used for speaker diaphragms.
The natural fiber is a cellulosic fiber (pulp or the like) or the like, and the speaker diaphragm is mainly composed of these natural fibers. If necessary, a chemical fiber is added in order to add rigidity as the diaphragm. Here, the chemical fibers include recycled fibers (rayon or the like), semi-synthetic fibers (acetate fibers), synthetic fibers, and inorganic fibers such as carbon fibers, graphite fibers, and glass fibers.

In order to obtain a loudspeaker diaphragm base material using these fibers, papermaking using a papermaking net generally performed can be used.

The loudspeaker diaphragm substrate thus obtained contains a fluorochloro-substituted derivative of a hydrocarbon.
In the present invention, it is necessary that the agent to be contained in the speaker diaphragm substrate be a fluorochloro-substituted derivative of a hydrocarbon.

As the fluorochloro-substituted derivative of the hydrocarbon used in the present invention, Freon (trade name: EI du)
Pont de Nemours & Co. Inc (manufactured by AI DuPont de Nemours) and the like are known. Freon includes, for example, Freon 11 (C
Cl ₃ F), Freon 12 (CCl ₂ F ₂ ), Freon 2
2 (CHClF ₂ ), Freon 113 (CCl ₂ FCCl
F _2), there is Freon 114 (CClF ₂ CClF ₂₎ or the like. These are used for producing a fluorinated resin, and a derivative polymer is obtained by suspension polymerization or emulsion polymerization in the presence of a peroxide or sodium sulfite catalyst.

Examples of the polymer obtained from such a fluorochloro-substituted hydrocarbon derivative include ethylene tetrafluoride polymer [(CF ₂ -CF ₂ ) _n ] and ethylene tetrafluoride-propylene hexafluoride polymer [(( CF ₂ -C
_{F 2) n - (CF (} CF 3) -CF 2) m) l], and the like vinylidene fluoride polymer ethylene polymers.

The critical surface tension of these derivative polymers derived from Freon, that is, fluorochloro derivative polymers of hydrocarbons, is extremely small. For example, dyn in polyethylene
e / cm, 33-43 dyne / cm for polystyrene,
The polyamide has a critical surface tension of 42 to 46 dyne / cm, while the fluorochloro derivative polymer of a hydrocarbon has a critical surface tension of 18 dyne / cm.

In order for a liquid to wet a solid surface, it must be less than this critical surface tension value. Here, the surface tension of water is 72.75 dyne / cm (20
° C), which indicates that the fluorochloroderivative polymer of hydrocarbon can impart excellent waterproofness to the substrate.

Further, the CF bond dissociation energy of the fluorochloro derivative polymer of hydrocarbon is 107 kcal /
mol, for example, C—H such as polyolefin resin.
The bond dissociation energy is larger than 103 kcal / mol. This means that the fluorochloro derivative polymer of the hydrocarbon is thermally stable. In fact, derivative polymers with Freon can be used in the temperature range of -50C to 150C.

As a method for incorporating such a fluorochloro derivative of a hydrocarbon into a diaphragm for a speaker, for example, a fluorochloro-substituted derivative of a hydrocarbon liquefied by means such as melting, dissolving or dispersing in a solvent, or the like is used. It is based on a method such as immersion impregnation, application, spraying, etc. on the speaker diaphragm substrate.

Among them, a fluorochloro derivative of a hydrocarbon is dissolved in water, an organic solvent such as alcohol, or a mixture thereof, and a diaphragm substrate for a speaker is immersed in a solution of the fluorochloro derivative of a hydrocarbon. The speaker diaphragm according to the present invention can be easily obtained by a simple method such as pulling up and drying.

Here, a water-soluble fluorochloro derivative of a hydrocarbon is available from Asahi Glass or the like, and immersion impregnation using such a solution can reduce the possibility of causing environmental problems. The speaker diaphragm of the present invention can be obtained without using a system solvent or a halogen solvent.

In the present invention, the content of the fluorochloroderivative polymer of a hydrocarbon in the diaphragm for a speaker is 0.5.
High waterproofness is obtained at 1% by weight or more and 1% by weight or less. Further, when the content is 0.5% by weight or more and 0.8% by weight or less, particularly high waterproofness is obtained. As described above, even if the content of the fluorochloro derivative of a hydrocarbon is small, high waterproofness can be obtained, so that the original physical properties (Young's modulus, internal loss, etc.) of the speaker diaphragm substrate are not impaired.

In the speaker diaphragm of the present invention, by providing a nitrocellulose resin layer or an acrylic resin layer, the Young's modulus can be increased.
The performance as a speaker diaphragm can be improved. When an acrylic resin layer is provided in the resin layer,
Water resistance can be further improved. From the detection of water repellency, when these resin layers are provided, it is desirable to further provide a layer made of a fluorochloro derivative of a hydrocarbon thereon. These layers may be provided on only one surface of the speaker diaphragm, or may be provided on both surfaces.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The speaker diaphragm of the present invention will be specifically described below. (Preparation of diaphragm base material) Using a beater, NUKP pulp is beaten to a SR of 20 degrees by a shopper Wrigler beating degree (based on JIS P8221). Further, synthetic fibers and inorganic fibers that contribute to the rigidity required for the diaphragm were added. These fiber materials were dispersed in a papermaking tank, papermaking was performed using a conical papermaking net, and then dried to obtain a speaker diaphragm substrate.

(Preparation of speaker diaphragm A (Example 1)) An impregnating solution having the formulation shown in Table 1 was prepared by using Asahi Glass AG-710 as a fluorochloro-substituted derivative of hydrocarbon.

[0024]

[Table 1]

The diaphragm base material prepared above was immersed in the impregnating solution, pulled up, dried, and then cut and molded into a predetermined shape to obtain a speaker diaphragm A according to the present invention. FIG. 1 shows a partially enlarged view (model enlarged view) of the speaker diaphragm A. As shown in FIG. 1, the fluorochloro-substituted derivative 22 of the hydrocarbon is substantially filled in the space between the pulp fibers 21 of the base material and is uniformly attached to the pulp fibers.

(Preparation of speaker diaphragm B (Example 2)) Nitrocellulose for achieving a high Young's modulus required as a speaker diaphragm is provided on the surface of the speaker diaphragm prepared in the same manner as the speaker diaphragm A. In order to achieve waterproofing of the nitrocellulose resin layer and the nitrocellulose resin layer, a speaker diaphragm B in which a fluorochloro-substituted derivative layer of a hydrocarbon was provided on the nitrocellulose resin layer was produced.

First, a loudspeaker diaphragm having a fluorochloro-substituted derivative of a hydrocarbon prepared in the same manner as the loudspeaker diaphragm A was impregnated with a nitrocellulose solution having the composition shown in Table 2 and then pulled up. After drying for 5 minutes, the nitrocellulose on the surface was cured to form a nitrocellulose resin layer.

[0028]

[Table 2]

Using the substrate having the nitrocellulose resin layer formed on the surface as described above, the fluorochloro-substituted derivative layer of a hydrocarbon is disposed on the nitrocellulose resin layer again using the impregnation solution shown in Table 1. The obtained speaker diaphragm B was obtained.

FIG. 2 is a partially enlarged view (model enlarged view) of the speaker diaphragm B. As shown in FIG. 2, the fluorochloro-substituted derivative 22 of the hydrocarbon is substantially filled in the space between the pulp fibers 21 of the base material, and is uniformly attached to the pulp fibers. A nitrocellulose resin layer 23 is laminated on both sides of the substrate, and a fluorochloro-substituted derivative layer 24 of a hydrocarbon is laminated on the nitrocellulose resin layer in this order.

(Preparation of speaker diaphragm C (Example 3)) Similarly to speaker diaphragm B, an acrylic resin solution whose composition is shown in Table 3 instead of the nitrocellulose solution shown in Table 2 , A nitrocellulose layer on a substrate layer comprising a fluorochloro-substituted derivative of a hydrocarbon and a fiber, and a speaker diaphragm further provided with a fluorochloro-substituted derivative layer of a hydrocarbon on the nitrocellulose resin layer C was prepared.

FIG. 3 is a partially enlarged view (model enlarged view) of the speaker diaphragm C. As shown in FIG. 3, the fluorochloro-substituted derivative 22 of the hydrocarbon is substantially filled in the space between the pulp fibers 21 of the base material, and is uniformly attached to the pulp fibers. Acrylic resin layers 2 on both sides of this substrate
5. Further, on the upper surface of the acrylic resin layer, a fluorochloro-substituted derivative layer 24 of a hydrocarbon is sequentially laminated.

[0033]

[Table 3]

(Evaluation of speaker diaphragms A, B and C)
The speaker diaphragms A, B, and C produced above were evaluated. For comparison, the diaphragm substrate itself before impregnation with the fluorochloro-substituted derivative solution of hydrocarbons was also evaluated as a diaphragm D for speaker according to the prior art (Comparative Example).

That is, the density (bulk density), Young's modulus and internal loss of these diaphragms were evaluated. These evaluation results are also shown in Table 4.

[0036]

[Table 4]

From Table 4, it can be seen that the speaker diaphragms A, B and C according to the present invention have the same bulk density and internal loss as the conventional speaker diaphragm, and the same Young's modulus (speaker diaphragm A). Or more (speaker diaphragms B and C having a resin layer).

Further, regarding these diaphragms A and B,
When the water repellency was examined in accordance with JIS P8137 (“Testing method for water repellency of paper and paperboard”), it was found that R8 to R9 had excellent water repellency.

The diaphragm C was not deformed even when left in an environment of 45 ° C. and 95% RH for 48 hours, and was not similarly deformed when immersed separately in water at 20 ° C. for 24 hours. From the results, it was confirmed that diaphragm C according to the present invention has extremely high water resistance.

Further, in addition to these diaphragms A to D, these diaphragms and center caps A ′ to D ′ manufactured in the same manner as A to D are used to form a diaphragm having the outline shown in FIG. And the functional performance evaluation as a speaker.

As a result, even when the diaphragms A to C containing the fluorochloro-substituted derivative of hydrocarbon and the center caps A 'to C' are used, the diaphragms D and D which do not contain the fluorochloro-substituted derivative of hydrocarbon are used. It was confirmed that the assembling work could be performed in exactly the same manner as when the cap D 'was used, and that the durability of these speakers was equal to or higher than that of the conventional speakers.

[0042]

The speaker diaphragm of the present invention is composed of a substrate made of natural fiber, chemical fiber or a mixture thereof, and has a structure containing a fluorochloro-substituted derivative of a hydrocarbon. This is an excellent speaker diaphragm that can be used in a field requiring particularly high waterproofness and does not require special processing or the like required for a conventional plastic diaphragm when assembling the speaker.

[Brief description of the drawings]

FIG. 1 is a partially enlarged view (model enlarged view) of a speaker diaphragm A (Example 1).

FIG. 2 is a partially enlarged view (model enlarged view) of a speaker diaphragm B (Example 2).

FIG. 3 is a partially enlarged view (model enlarged view) of a speaker diaphragm C (Example 3).

FIG. 4 is a model sectional view of an example of a general electrodynamic speaker.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 back plate 2 pole piece 3 magnet 4 plate 5 voice coil 6 voice coil bobbin 7 damper 8 diaphragm 9 center cap 10 edge 11 frame 12 gasket 21 pulp fiber 22 hydrocarbon-substituted derivative of hydrocarbon 23 nitrocellulose resin layer 24 hydrocarbon fluorocarbon Substituted derivative layer 25 Acrylic resin layer

Continued on the front page (72) Inventor Masanori Takahashi 954-1, Shiono, Shimmachi, Mamurokawa-machi, Mogami-gun, Yamagata F-term (reference) in Mogami Denki Co., Ltd. 5D016 AA15 CA04 DA01 EA01 EA04 EA05 HA07

Claims (1)

[Claims] 1. A speaker diaphragm comprising a substrate made of natural fiber, chemical fiber or a mixture thereof, and containing a fluorochloro-substituted derivative of a hydrocarbon.