EP2986447A1

EP2986447A1 - Composite for production of an acoustic membrane and acoustic membrane

Info

Publication number: EP2986447A1
Application number: EP14714270.7A
Authority: EP
Inventors: Michael Egger; Bernhard MÜSSIG; Philip SCHULTZ
Original assignee: Tesa SE
Current assignee: Tesa SE
Priority date: 2013-04-16
Filing date: 2014-03-31
Publication date: 2016-02-24
Also published as: CN105142895A; JP2016521056A; DE102013206812A1; US9827749B2; KR20150143730A; US20160052246A1; TW201501549A; BR112015025937A2; WO2014170122A1

Abstract

The invention relates to a composite for production of an acoustic membrane, wherein the composite comprises an internal carrier layer and at least two adhesive layers on the two surfaces of the carrier layer, and wherein the carrier layer is a layer of a polyaryl ether ketone film; and also to a corresponding membrane for acoustic transducers.

Description

Composite for the production of an acoustic membrane and acoustic membrane

The invention relates to a layer composite suitable for producing membranes for electroacoustic transducers, comprising a carrier layer and two damping layers arranged on the surfaces of the carrier layer.

Electroacoustic transducers, also referred to as sound transducers, are devices which convert electrical signals, that is to say electrical voltage, into sound pressure changes, that is to say acoustic signals, or vice versa. Examples of sound transducers are the loudspeaker as a sound generator and the microphone, the sensor and the pickup as a sound receiver.

In mobile phones, smartphones, notebooks, tablet PCs, personal digital assistants (PDAs) and headphones, the generation of sound, ie the transmission of speech, ringtones, music and other sounds and sounds, via so-called micro-loudspeakers. These are loudspeakers which, due to the small dimensions of the devices in which they are installed, are also small in size. The acoustic signals are thereby generated by the movement of a loudspeaker diaphragm, e.g. is mechanically driven by a voice coil. The demands, in particular on the achievable volume of these microspeakers, are becoming increasingly demanding. Due to the increasing power and the associated higher temperature load and higher demands are placed on the thermal stability of the membranes of these microspeakers and their functionality under thermal stress, so that conventional membrane materials such as polyethylene terephthalate (PET) or polycarbonate (PC) encounter their limits more often ,

The essential requirements for the material of a loudspeaker membrane include a high flexural rigidity, a low density and a high internal damping. To meet these requirements as well as possible, are increasingly used as a loudspeaker membranes multi-layer laminates. In such multi-layer laminates, rigid plastic films are combined with soft, acoustically damping layers lying between these films. The acoustic damping properties are closely related to the mechanical damping properties of these layers.

Since the membranes heat up strongly at high power during operation and especially in micro loudspeakers - for example up to loudspeaker sizes up to 50 mm x 30 mm x 10 mm; typical microspeaker sizes in the market are, for example, 5 mm × 10 mm × 2 mm and 8 mm × 12 mm × 2 mm - due to their small dimensions, temperatures of 100 ° C. and more can be achieved, the external films used not only have a high rigidity, but additionally also have a good temperature resistance. In the past few years, the high-performance plastic polyetheretherketone (PEEK), which is frequently used in multilayer laminates with additional soft damping layers, has proven to be a very suitable material for the outer films.

Based on the abovementioned three-layer laminates, in the case of five-layer laminates, the inner, damping layer is interrupted by a further, inner layer. According to the so-called sandwich theory, the multilayer laminates follow the principle that a high flexural rigidity of multilayer or sandwich membranes is achieved by using the stiffest layers on the outside and including softer inner layers. Accordingly, the rigid PEEK films are always used as outer layers, and the inner layers proposed in the prior art are significantly softer.

Thus, EP 2 172 059 A describes a five-ply laminate consisting of two outer PEEK films which are applied to both sides of a non-woven fabric, each with one layer of a thermoplastically deformable adhesive. Here, the two outer PEEK films take over the function of giving the laminate a high flexural rigidity, while the inner soft layers (adhesives, fleece) provide good internal damping of the composite. Another five-layer laminate describes the US 201 1/0272208 A. This is composed of two outer layers of film (called as material for the outer films PEEK next to some other plastics), with the help of an acrylic adhesive on the two sides of a PET film are applied. According to this document, the membrane achieved by this multi-layer structure has a longer life than a three-layer laminate of two outer layers of film, such as polyarylate (PAR) films, and a lying between these films damping adhesive layer.

Due to the low glass transition temperature of polyethylene terephthalate (about 70 ° C in the DSC at a heating rate of 10 K / min) occurs when a warming of this material to a strong decrease in stiffness, which is related to the increasing softening of the material and in a significant drop in the Modulus of elasticity shows (the stiffness of the film materials used for loudspeaker membranes is described by the so-called modulus of elasticity - also modulus of elasticity or tensile modulus - defined by the ratio of stress to strain in the deformation of the material in the linear elastic range). As mentioned above, however, acoustic membranes in use heat up strongly, so that the PET film is also a soft inner layer in the application and even after introduction of a plastic film as a middle layer in the product structure, the above sandwich theory is not broken, according to the the stabilizing layers should be on the outside and the damping layers inside. Consequently, the disclosure of this document is also limited to PET as a material for this inner film layer. Designs for the concrete design of the membrane are not disclosed in the document.

The product constructions in which PEEK is used in the outer layers because of its good flexural rigidity properties are relatively expensive, partly because of the use of two external PEEK films. In addition, all other outward-facing properties of these membranes are determined by PEEK as external material.

It is considered an object of the invention to find alternative product structures which are particularly advantageous to produce more cost-effective, but their good properties in terms of high flexural stiffness, low density and high internal Do not lose damping and preferably allow a good adaptation of the properties to the particular application.

Surprisingly, this object could be achieved by using a PEEK film as a stabilizing film as the inner support layer of a membrane, which can be used in particular for use in electroacoustic transducers. It has been found that the use of only one PEEK film as a central middle layer is already sufficient to give not only a high flexural rigidity to a multilayer laminate as a whole, but also a sufficient stability, which ensures a long service life of the membrane in the application provides. The damping properties are effected in particular by layers arranged on the surfaces of the membrane, preferably by adhesive layers, very preferably by self-adhesive layers (also referred to as PSA layers). This also makes it possible to offer a three-layer composite as a building block for the individual completion of a five- or multi-layer laminate membrane.

The invention therefore relates to a three-layer composite, cf. FIG. 2, comprising an inner film layer (2) and two damping layers (1, 3) arranged on the surfaces of this film layer, of which at least one damping layer is preferably an adhesive layer, particularly preferably both layers of adhesive layer are -, wherein the inner film layer (2) is a layer of a polyaryletherketone (PAEK), in particular of polyetheretherketone (PEEK), is.

Such a three-layer composite, in particular with layers of adhesive layers-more preferably self-adhesive layers-as damping layers, can be used excellently for producing a five-layer composite for further use or production of a membrane for use with electroacoustic transducers, for example loudspeakers, such as microspeakers, in particular by applying to the Further outer film layers (4, 5) are arranged on both outer adhesive composition surfaces (1, 3) and thus an at least five-layered laminate is produced, cf. FIG. 3.

The composite according to the invention is particularly well suited for use in membranes for microspeakers with sizes of 50 mm × 30 mm or less, especially for very small microspeakers whose maximum extent (ie Length in the direction of its greatest extent) does not exceed 25 mm, in particular does not exceed 15 mm.

Membranes for microspeakers may, for example, be round, oval, rectangular, square or else shaped in their surface area.

An externally non-sticky three-layer composite can be used excellently even without further outer layers for further use or production of a membrane for use with electroacoustic transducers.

Four-layer laminates may also be produced and used for further use or manufacture of a membrane for use with electroacoustic transducers; in particular of three-layer composites, in which one of the damping layers is an adhesive layer, more preferably a self-adhesive layer.

Due to the construction according to the invention, it has been detached from the theory of sandwich theory that the bending stiffness of the overall product is granted by the outer layers. The assumption that a very stiff middle layer would adversely affect the damping properties of the overall product was surprisingly not confirmed for the product design according to the invention.

This was not to be expected insofar as, according to the sandwich theory, a high flexural rigidity of multilayer or sandwich membranes is achieved precisely by the fact that the stiffest layers are used on the outside and include softer inner layers (see also above, see also Plantema, F, J., 1966, Sandwich Construction: The Bending and Bending of Sandwich Beams, Plates, and Shells, Jon Wiley and Sons, New York; Zenkert, D., 1995, Introduction to Sandwich Construction, Engineering Materials Advisory Services Ltd, UK; Latin American Journal of Solids and Structures, 2012, 9, 367-381 Figure 1 shows a three-layer laminate according to the sandwich theory with a damping inner layer K and two outer stiff layers A). As stated above, the prior art five-layer laminates membranes also follow this teaching because the respective inner layers are made of either permanently soft materials (such as nonwovens) or of those materials that are soft at least in use (such as PET) are. On the basis of this theory, the skilled person would not have used as an inner carrier layer materials which are also "hard" at relatively high temperatures, in particular polyaryl ether ketones such as PEEK Glass transition temperature of PEEK at 144 ° C (DSC, heating rate 10 K / min) is significantly higher than that proposed in US 201 1/0272208 PET film. A significant softening of the PEEK film therefore takes place, in contrast to PET, only significantly above the temperatures that occur for the membrane in their application.

The three-layer composite of a central polyaryletherketone film layer (in particular PEEK film layer) and two adhesive layers arranged on the two surfaces of this PAEK film layer - in particular self-adhesive layers - represents a double-sided adhesive tape - in particular self-adhesive tape - offer adhesives as a damping layer (s) the advantage that they - especially in self-adhesive properties - on the one hand can be excellently anchored on the support layer and on the other hand have the required acoustic damping properties. It has been found that the good damping properties of the overall system are not significantly impaired even if the damping layer is interrupted by an inserted intermediate layer of a relatively stiff foil material - here the PAEK or PEEK carrier layer.

In the application of a composite layer as a membrane for acoustic transducers, however, an outward (sticking) tackiness is undesirable, since this would lead to poor handling of the membrane and also to its contamination (for example due to strong dust adhesion). This would also affect the properties required for the acoustics. Preferably, therefore, at least one, preferably both outer adhesive layers are provided with a temporary (ie removable) or a permanent cover, so that a four, in particular a five-layer laminate results.

For the handling of the three-layer composite, in particular if this is to be sold as a separate module to customers who in turn produce the desired membrane of them, it is advantageous if one or both adhesive surfaces with a temporary cover, in particular a liner - for example release paper , Release film or with release material, such as silicone, coated plastic or paper films - are equipped, which in particular provides protection of the adhesive layer, but can be easily removed again. This allows the customer, in principle, the outside films to free and to adapt for the use of the product as an acoustic membrane in each case the desired application or speaker model. Both the necessary flexural stiffness, the stability of the ultimately present membrane and the damping properties are already perfectly met by the described three-layer system, so that the outer films can be optimally selected with regard to certain desired further product properties, such as temperature resistance or cost aspects.

A five-layer laminate, in particular for the production of membranes for electroacoustic transducers, can be obtained by arranging permanent covering layers on both outer adhesive layers, in particular film layers which can be chosen the same or different on both sides. In one embodiment of the invention, these permanent layers are applied after the temporary covers have been removed.

The fabrication of membranes for electroacoustic transducers, particularly loudspeaker membranes, is often accomplished by embossing or deep drawing a multilayer laminate, thereby rendering this laminate in a specific three-dimensional shape. For this purpose, the multi-layer laminate is cut, for example, to the desired dimensions and then placed on a thermoforming. Subsequently, the laminate is heated in the thermoform and pressed by applying pressure and / or vacuum in the form of the finished membrane.

As a result of the fact that it has now been shown that the use of only one central PAEK layer, preferably a PEEK layer, already gives the laminate sufficiently high rigidity, a multiplicity of different materials can also be used with lower stiffnesses as outer layers in the composite. This has the advantage that on the one hand the acoustic properties of the membrane can be set very variable and at the same time one of the two very expensive external films can be replaced by less expensive films, which reduces the cost of the entire laminate.

Due to the high stiffness of PAEK films - such as the PEEK film - even at higher temperatures, it is possible to use very thin films as carrier films and yet to ensure sufficient stability of the composite. By using a particularly thin, double-sided adhesive-coated PEEK Film can thus be produced easily by laminating different layers of a variety of different multi-layer laminates with tailor-made acoustic properties in a simple manner. The PAEK film (in particular PEEK film) ensures the high rigidity of the laminate, while the two layers of adhesive on both sides of the film ensure the simultaneous high internal damping of the laminate.

In a preferred embodiment, the PAEK film functioning as a carrier layer has a thickness of from 1 to 50 μm, more preferably from 1 to 30 μm, particularly preferably from 2 to 25 μm; and / or advantageously have the adhesive layers independently of one another in each case a thickness in the range of 1 to 100 μηη, preferably in the range of 1 to 50 μηη, particularly preferably in the range of 2 to 40 μηη on. Even if the adhesive layer thicknesses can be selected independently of one another, such three-layer laminates in which the thicknesses of the two layers of adhesive layers are selected from the same of the aforementioned ranges, in particular symmetrical adhesive tapes, have proven to be particularly suitable for the application or production of five-layer laminates for acoustic membranes ,

The present invention therefore furthermore relates, in particular, to a composite comprising, in particular, a thin, PEEK film, provided on both sides with an adhesive layer, (see FIG

- The thickness of the central PEEK film (2) 1 -50 μηη, preferably 1 -30 μηη, more preferably 2-25 μηη is and

- The thicknesses of the adhesive layers (1) and (3) independently of one another 1 -100 μηη, preferably 1-50 μηη, particularly preferably 2-40 μηη amount.

The adhesives on both sides of the central PAEK film, in particular PEEK film, are preferably self-adhesive compositions. Self-adhesive compositions, PSA (pressure sensitive adhesives), are understood to mean, in particular, polymeric compositions which, if appropriate by suitable addition with other components, such as, for example, tackifier resins, are used at the application temperature (unless otherwise defined, at room temperature). permanently sticky and permanently tacky and adhere to a variety of surfaces upon contact, in particular immediately adhere (a so-called "tack" [stickiness or Anfassklebrigkeit] have). You are already able to Application temperature without activation by solvent or by heat - but usually by the influence of a more or less high pressure - sufficient to wet a substrate to be bonded, so that between the mass and the substrate for the adhesion sufficient interactions can form. Factors influencing this process include pressure and contact time. The special properties of the PSAs are due in particular to their viscoelastic properties.

Advantageously, acrylate PSAs are used for the adhesive layers. These are adhesives whose polymer base are polymers of acrylic monomers - these are in particular acrylic and methacrylic acid, the esters of the aforementioned acids and the copolymerizable further derivatives of the aforementioned acids understood -, the acrylic monomers - optionally together with other comonomers - in the polymerization at least be used in an amount that the properties of the adhesive are thereby determined significantly. Thus, for example, pressure-sensitive adhesives having an acrylic monomer content in the polymerization of at least 50% by weight, of at least 80% by weight or of 100% by weight (pure acrylate systems) can be used.

Other adhesives familiar to the person skilled in the art are also possible and can be used in the context of the invention. The adhesives on both sides may be identical or different from each other.

For the production of membranes from multilayer laminates based on the double-sided adhesive PAEK film (in particular PEEK film), for example, a method can be used in which other high-temperature-resistant plastic films on both sides - ie on the respective adhesive surfaces - laminated. Film materials which may be used include polyarylates (PAR), polyetherimides (PEI), polyarylsulfones such as polyphenylene sulfone (PPSU) and polyethersulfone (PES). For example, polyphenylene sulfide (PPS), polyethylene naphthalate (PEN), polybutylene terephthalate (PBT), polyimide (PI) and polysulfone (PSU) are also possible as film materials for one or both outer films. In principle, it is of course also possible to choose as one or both of the outer film layers polyaryletherketones, such as PEEK. It is also possible to produce multi-layer laminates of the claimed product by the two adhesive layers of the inner Three-layer composite on the outer sides are covered by varnishes, nonwovens or fabric.

The outer film layers can advantageously independently of one another in thicknesses of 1 to 50 μηη, more preferably from 1 to 30 μηη, particularly preferably from 2 to 25 μηη are selected, in particular to be identical for producing a symmetrically constructed membrane.

An example of a three-layer composite according to the invention was obtained by coating a PEEK film of thickness 6 μm (trade name Aptiv 2000-006G from Victrex), both sides of the film being coated with a 12 μm thick acrylate PSA. This composite was then laminated on both sides, each with a 6 μηη thick PAR film (Aryphan N681 EM from Lofo).

This laminate was brought by a conventional embossing process in membrane form (rectangular, 17 mm x 13 mm, thicknesses before embossing 42 μηη) and made according to the usual method of making a micro-speaker. The micro loudspeaker had no disadvantages of the acoustic properties in the application test compared to a microfabricator of identical construction with a commercially available PAR acrylate layer PAR three-layer membrane (comparative membrane 1), but had a longer service life compared to the comparison membrane 1. Compared with a membrane of US Pat. No. 2,791,220 (with external PEEK foils, thickness of the inner PET layer 6 μηη, thickness of the layers of adhesive 12 μηη of an acrylate, for the preparation of the comparative membrane selected identical to the membrane according to the invention, outer PEEK films each 6 μηη; Comparative membrane 2) produced micro speaker showed a smoother frequency response and a lower harmonic distortion in the customer service test, and the membrane was also cheaper to produce.

Claims

claims

1 . Composite for producing an acoustic membrane, wherein the composite comprises an inner support layer and at least two adhesive layers on the two surfaces of the support layer, characterized in that the support layer is a layer of a polyaryletherketone film.

2. Composite according to claim 1, characterized in that

the polyaryletherketone film is a polyetheretherketone film.

3. Composite according to one of the preceding claims, characterized in that at least one of the adhesive layers is a self-adhesive layer.

4. Composite according to one of the preceding claims, characterized in that both adhesive layers are self-adhesive layers.

5. Composite according to one of the preceding claims, characterized in that the adhesive is at least one adhesive layer, in particular both adhesive layers, acrylate adhesives.

6. Composite according to one of the preceding claims, characterized in that the thickness of the inner PAEK film layer 1 to 50 μηη, preferably 1 to 30 μηι, more preferably 2-25 μηη

and or

the thicknesses of the adhesive layers independently of one another are in each case from 1 to 100 μm, preferably from 1 to 50 μm, particularly preferably from 2 to 40 μm.

7. Composite according to one of the preceding claims, characterized in that a liner is arranged on at least one of the two outer surfaces of the adhesive layers, in particular on both surfaces.

8. Composite according to one of the preceding claims, characterized in that a further plastic film is arranged on at least one of the two outer surfaces of the adhesive layers, in particular on both surfaces.

9. Composite according to claim 8, characterized in that

the thicknesses of the outer plastic films independently of one another are in each case from 1 to 50 μm, preferably from 1 to 30 μm, particularly preferably from 2 to 25 μm.

10. Composite according to one of the preceding claims, characterized in that the product structure is symmetrical with respect to the layer thicknesses and / or with respect to the composition of its layers.

1 1. Membrane for electroacoustic transducers, in particular loudspeaker membrane, obtainable by embossing or deep-drawing a composite according to one of the preceding claims.

12. Use of a membrane according to claim 1 1 for the production of electro-acoustic transducers, in particular for the production of loudspeakers.