The present invention relates to a magnetic material, and a method of manufacture of such a material.
Magnetic materials (e.g. high magnetic permeability materials) are used in a variety of applications, such as within electrical motors and as magnetic shielding for electronic devices. Such materials are typically metal alloys (e.g. mu-metal and permalloy) comprising one or more of nickel, iron, copper and molybdenum. Accordingly these materials are rigid, requiring machining to form shaped components, with such machining having associated cost implications. Further, such materials have a large mass making them undesirable for light-weight applications.
A further high permeability magnetic material comprises a high magnetic permeability particulate suspended in a rubber material. A still further material which is available is supplied by 3M under the designation AB-5000. This material is described as an EMI absorber which consists of a polymer resin (with acrylic pressure—sensitive adhesive) filled with soft metal flakes. The material has application for magnetic shielding and is supplied in thicknesses of 0.1, 0.2, 0.3, 0.5 and 1.0 mm. These materials are however of a relatively “closed” structure so are difficult to infuse with additional materials (e.g. resins) to tailor mechanical properties.
It is an object of the invention to obviate or mitigate the above mentioned disadvantages.
According to a first aspect of the invention, there is provided a magnetic material comprising a matrix of fibres which have a coating of a magnetic metal or alloy and magnetic particles bonded to said matrix.
The magnetic material of the invention comprises a fibre matrix which has been produced from fibres coated with a magnetic metal or alloy, and magnetic particles bonded to the non-woven fibre matrix.
According to a second aspect of the present invention there is provided a method of producing a magnetic material comprising preparing a fibre matrix from fibres coated with a magnetic metal or alloy, and bonding magnetic particles to the matrix.
Magnetic materials in accordance with the invention have a number of advantages arising from the fact that they comprise a fibre matrix comprised of fibres which have a coating of magnetic metal or alloy and magnetic particles bonded to the fibre matrix. In particular; the fibre matrix allows the material to be conformable which is an advantage for many applications, e.g. in surface engineering composite applications in the aerospace or automotive industries to deliver a smooth surface. Furthermore the magnetic properties of the material may be tailored by the type and/or amount of magnetic particles bonded to the fibre matrix and also by the type and/or thickness of the magnetic coating on the fibres. Additionally materials in accordance with the invention may be produced with a range of basis weights which may be tailored for the particular end use application of the material. On a related point, it is thus possible for materials in accordance with the invention to be lighter than prior art materials. A further advantage that may be mentioned is that the porous structure of the materials of the invention allows them to be fused with additional materials (e.g. resins), e.g. to enhance strength or other mechanical properties.
Materials in accordance with the invention are useful for providing magnetic shielding. Examples include use (for shielding) in medical devices and equipment, magnetic sensors for compassing in passenger automobiles, cell phones and hand-held GPS receivers, along with compassing and dead reckoning in vehicle, aircraft, marine and personal navigation.
The matrix may be produced as a 2-dimensional or 3-dimensional shape by a vacuum forming process.
Materials in accordance with the invention may be readily prepared by bonding the magnetic particles to a pre-formed fibre matrix. Any of a wide variety of conventional adhesive agents may be used for bonding the magnetic particles to the fibre matrix but it is particularly preferred to use a dispersion of a water-dispersible polymer. A suitable product is Eastman WD-30 which is an aqueous dispersion containing 30% by weight of an amorphous sulfopolyester. Further examples include styrene-based and acrylic polymers. For the purposes of this procedure, the magnetic particles may be dispersed in the dispersion of the adhesive/binding agent to produce a coating composition which is applied using conventional techniques to the base fibre matrix. Subsequently the coated matrix may be dried (e.g. using a conventional oven).
The magnetic particles are preferably provided as a uniform coating on one or both sides of the base matrix of fibres.
Magnetic materials in accordance with the invention will generally have a total basis weight (calculated as total weight of the fibre matrix plus magnetic particles divided by area) of 1 to 1000 gm−2, and more preferably 2 to 500 gm−2, e.g. 5 to 500 gm−2. More preferably, the total basis weight will be in the range of 10 to 200 gm−2 and most preferably 20 to 150 gm−2. Typically the basis weight of the fibre matrix will be in the range 3 to 250 gm−2 with a preferred sub-range of 5 to 100 gm−2, most preferably 10 to 75 gm−2, with the remainder of the total basis weight being provided by the magnetic particles and any binder used for bonding the magnetic particles to the fibre matrix. Typically the amount of magnetic particles will be in the range 5 to 300 gm−2, preferably 5 to 100 gm−2, of the fibre matrix.
The fibres that form the matrix have a coating of a magnetic metal or metal alloy. If a metal alloy is used then it will comprise at least one magnetic material and alloying elements to provide required properties (e.g. a particular conductivity). The magnetic metal or magnetic metal alloy may comprise one or more metals selected from iron, nickel, copper, cobalt, gadolinium, silver, gold, chromium, ruthenium, tin, zinc and manganese, provided that there is at least one magnetic metal. The coating preferably includes at least one ferromagnetic metal. It is particularly preferred that the metal coating comprises an iron-nickel alloy, for which purpose a wide range of nickel:iron ratios may be used although generally the ratio will be in the range 80:20 to 45:55. A nickel:iron ratio of 80:20 provides the highest saturation capability whereas a nickel:iron ratio of 45:55 provides the highest permeability.
It is particularly preferred that the coating is of a high magnetic permeability metal e.g. from 200 Hm−1 for stainless steel to 30,000 Hm−1 for mumetal.
A variety of different (“core”) fibres (i.e. fibres that are coated with the magnetic material or alloy) may be used for forming the non-woven fibre matrix. The fibres may, for example, may be vitreous fibres or synthetic polymer fibres. Alternatively the non-woven fibre matrix may be comprised of carbon fibres which are advantageous since they do not expand significantly on heating (i.e. they have a very low thermal expansion which is mainly positive depending on the exact application).
Particularly preferred fibres for use in accordance with the invention comprise carbon fibres coated with an iron/nickel alloy thereby providing low thermal expansion with maximised magnetic properties for the material.
It is preferred that all fibres that make up the matrix have a coating of magnetic metal or magnetic metal alloy but we do not preclude the possibility of the presence (in the matrix) of uncoated fibres. Generally at least 5% by weight of the fibres of the matrix will have a coating of the magnetic metal or metal alloy. More typically at least 50% of the fibres will have such a coating, more usually at least 75% and preferably at least 90%, the ideal being 100%.
The magnetic particles bonded to the fibre matrix will generally comprise at least one of iron, cobalt and nickel to impart ferromagnetic properties to the particle matrix. The particles may comprise more than one such ferromagnetic element and alternatively or additionally may incorporate alloying elements (such as chromium, manganese and/or molybdenum) usually in a total amount of somewhat less than the amount of ferromagnetic material present in the particles.
The magnetic particles will generally have size dimensions in the range 1 nm to 200 μm, more preferably in the range 10 nm to 100 μm and even more preferably in the range 1 to 20 μm as determined by a d50 measurement light scattering technique typically by using an instrument such as a Malvern Mastersizer 2000. The particles may be “flake-like” as a result of the process by which the manufactured and as such have a thickness somewhat less than both their length and width. Typically the thickness of such “flake-like” particles will be in the range 10 nm to 20 μm with the length and width being up to 100 μm.
Magnetic particles which are particularly suitable for use in the invention are available from Silberline Manufacturing Co. Inc. under the following designations:
Stainless Steel Pigment RMT441
Stainless Steel Pigment RMT442
Stainless Steel Pigment RMT468
The above three products all comprise particulate iron alloy in Stoddart Solvent which is removed by washing (e.g. using 70920 Dowanol® PM supplied by Kremer Pigmente) to render the particles suitable for use in producing composite materials in accordance with the invention. The '441 product comprises an alloy of iron and chromium, the '442 product comprises an alloy of iron, nickel, chromium, manganese and molybdenum, and the '468 product comprises an alloy of iron, chromium and nickel. Blends of two or more of these products may be used.
A further material that may be used is MRK 254 Stainless Steel Flake (also available from Silberline) which comprises 69% iron, 17% chromium, 12% nickel and 2% molybdenum (the percentages being by weight) and which may be milled or otherwise comminuted to an appropriate particle size for use in the invention.
The fibre matrix may be a non-woven fibre matrix and preferably a non-woven fibre matrix in which the fibrous structure of the matrix has been produced at least predominantly from staple fibres. In the context of the present invention, staple fibres have a length of less than 200 mm, more preferably less than or equal to 150 mm, and even more preferably less than or equal to 100 mm. The staple fibres may have a length less than or equal to 50 mm. As indicated, the preferred non-woven fibre matrix in accordance with the invention is one in which the fibrous structure of the matrix is comprised at least predominantly of staple fibres. Preferably the matrix is comprised of at least 90% of staple fibres (e.g. with a balance of non-staple fibres) and is ideally comprised of 100% by weight of staple fibres.
Alternatively the fibrous structure of the matrix may be produced other than as a non-woven fibre matrix and preferably other than a non-woven matrix in which the fibrous structure is comprised at least predominantly of staple fibres. Thus the fibrous structure of the matrix may be one produced at least predominantly with non-staple fibres. In the context of the present invention, non-staple fibres have a length of at least 200 mm, more preferably at least 500 mm. It should be appreciated that fibre matrices produced at least predominantly with non-staple fibres may (if desired) may be cut into smaller sections such that the fibres therein have a length of less than 200 mm. For example, the fibre matrix have been produced as a woven or knitted structure from non-staple fibres (and then cut to size as required). A further possibility is for the matrix to be comprised of at least one layer of non-staple fibres in which (in said layer) the fibres are unidirectional, i.e. all the fibres in that layer extend in the same direction. Such matrices may comprise a laminate of two or more layers, in each of which the fibres are unidirectional although possibly extending in different directions as between the various layers. Expressed alternatively, the fibres of one layer may all extend in one direction relative to each other whereas the fibres of another layer may all extend in one direction relative to each other but in a different direction to the fibres of the first mentioned layer. Similarly for any other layers in the structure. In any one layer, the unidirectional fibres will extend continuously from one edge of the layer to an opposite end thereof.
As indicated, the fibre matrix may be one in which the fibrous structure has been produced at least predominantly from non-staple fibres. Such matrices may be comprised at least 90% of non-staple fibres (e.g. with a balance of staple fibres) and are ideally comprised of 100% by weight of non-staple fibres.
It is preferred that the fibre matrix is a non-woven fibre matrix comprised at least predominantly of staple fibres, more preferably one produced by a conventional wet-laying technique. In conventional manner, such a process may comprise the steps of:
The non-woven fibre matrix may be one in which the staple fibres are held together by a cured binder.
Irrespective of fibre type, the fibres of the matrix will generally have a length in the range 1-100 mm (preferably 3-25 mm) and a cross-sectional thickness of 4-15 μm. Such fibres may initially be produced in tows which are then chopped into the form of staple fibres of desired length for use in producing the non-woven fibre matrix.
In the case where the fibre matrix, it is preferred that the magnetic particles are bonded to a pre-formed non-woven fibre matrix. We do not however preclude the possibility of forming the material in accordance with the invention by wet-laying a dispersion of the fibres which also contains the magnetic particles.
If the fibrous structure of the fibre matrix of the material in accordance with the invention is comprised at least predominantly of staple fibres then as outlined above it may for example be a woven or knitted structure or one comprising at least one layer of unidirectional fibres. Woven and knitted fibre matrices may be produced from tows of the fibres using conventional weaving and knitting techniques respectively. The individual tows may be bonded to each other with an appropriate binder resin, e.g. an epoxy resin.
If the matrix is comprised of a at least one layer of unidirectional fibres then each layer may be produced individually by laying tows of the fibres adjacent to each other in parallel relationship and bonding the twos together by means of a suitable resin, e.g. an epoxy resin. If the material is to comprise two or more layers of unidirectional fibres then each individual layer may be produced in the manner described and the individual layers then bonded to each with the unidirectional fibres of one layer being at any desired orientation relative to those of the other layer(s). In this way it is possible to build up quasi-isotropic structures.
The magnetic properties of materials in accordance with the invention may be tailored to a desired level in a number of ways, e.g.
In the case of a non-woven fibre matrix comprised of at least predominantly of staple fibres and produced by a wet-laying process, the orientation of fibres (with their magnetic coating) in accordance with (v) above may be effected/controlled by application of a magnetic field during the wet-laying process. By aligning the fibres it is possible to produce a denser structure for the non-woven matrix (particularly in the case where the fibres are carbon fibre—a relatively rigid material), thus influencing its magnetic properties. Similarly, with regard to (vii), orientation of magnetic particles may be controlled by use of a magnetic field during the step of applying the particles to the fibre matrix (irrespective of type). Particle orientation is appropriate, for example, in the case where the particles are regular in structure or “flake like” such that, in the latter case, the flakes may be oriented in generally the same direction. Particle distribution (i.e. possibility (viii) above) may in the case of a non-woven fibre matrix produced by a wet-laying process be effected by controlled drying of the non-woven web on or in which the particles have been incorporated. Thus, for example, drying the web at one side only will cause a preferential migration of particles to that side, which may be beneficial for the final magnetic properties of the material.
Magnetic materials in accordance with the invention may have a coercivity of 1 to 500,000 Oe, e.g. 1 to 10,000 Oe at ambient temperature. The material in accordance with the invention may be a “soft magnetic material” having a coercivity of 1 to 10 or a “hard magnetic material” having a coercivity of 1000 to 10,000.
The materials may have a magnetic permeability of 1 to 1000 Hm−1.
The material may have a saturation magnetisation of 10 to 3000 emu/cm3 (preferably 1500 to 2000 emu/cm3). The material may have a saturation magnetisation of 1 to 500 emu g−1, preferably 5 to 100 emu g″1, even more preferably 20 to 40 emu g−1.
The invention will be illustrated by the following non-limiting Examples and accompanying drawings, in which:
This Example demonstrates the application of a coating of magnetic particles to a non-woven matrix comprised of nickel-coated carbon fibres having a length of 12 mm and diameter of 7 μm. The non-woven fibre matrix had a basis weight of 10 gm−2 and was prepared using a standard wet-laying technique such as used for the manufacture of paper.
A water-based dispersion with an overall solids content of 12.4% by weight was prepared from a mixture of the following components in the indicated amounts.
1 SSP RMT441
1 SSP = Stainless Steel Pigment
Prior to forming the dispersion, the SSPs were prepared by washing the Stoddard solvent out with 70920 Dowanol® PM (supplied by Kremer Pigmente). The particles were then dried before adding to the other ingredients. The weights of the SSP products quoted in the above table are the weights of the washed and dried particles.
The dispersion was applied to the non-woven fibre matrix (comprised of nickel coated carbon fibres) at a rate of 690 gm−2 using a laboratory coater. The non-woven matrix to which the dispersion had been applied was then dried in a oven.
The resulting product comprised the non-woven fibre matrix with a coating of 110 gm−2 of metal particles and polymer binder (total basis weight=120 gm−2 including the non-woven fibre matrix).
The 110 gm−2 coating comprised:
The material was found to have the following magnetic properties:
This Example investigates the magnetic properties of various materials in accordance with the invention with the invention obtained by bonding magnetic particles to non-woven fibre matrices comprised of carbon fibres plated with nickel alloy coated carbon fibres. The fibres of the matrix had a length of 6 mm and diameter of 6-10 μm. Overall the fibres comprised 42-50% by weight of the alloy which itself had a composition of 80% nickel and 20% iron (reflecting a mumetal type material).
MRK 254 Stainless Steel Flake (ex Silberline) was milled and the resulting product used as the magnetic particles for this Example. Using a Mastersizer 2000 (Malvern Instruments) the particles were determined to have a specific surface area of 0.964 m2/g and have values for d(0.1), d(0.5) and d(0.9) by volume as follows:
d(0.1)=3.148 μm
d(0.5)=8.702 μm
d(0.9)=20.159 μm
For the purposes of this Example, non-woven fibre matrices having basis weights of nominally 20, 30 and 40 gm−2 were produced from the metal plated carbon fibres using conventional paper-making techniques.
Following the procedure of Example 1, the water based dispersion described therein (solids content=12.4% by weight was used to produce materials in accordance with the invention with a range of coating weights from each of the three non-woven fibre matrices (basis weights nominally 20, 30 and 40 gm−2). The following Table shows details of the materials produced and their measured magnetic properties together (for comparison) with measured properties for AB-5000 (ex 3M) having a thickness of 0.5 mm.
Reference is now made to
It can be seen from
Number | Date | Country | Kind |
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0917257.8 | Oct 2009 | GB | national |
Number | Date | Country | |
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61457476 | Apr 2011 | US |
Number | Date | Country | |
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Parent | PCT/GB2010/001857 | Oct 2010 | US |
Child | 13437314 | US |