WO1984002445A2 - Article having magnetic properties and production thereof - Google Patents

Article having magnetic properties and production thereof Download PDF

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Publication number
WO1984002445A2
WO1984002445A2 PCT/GB1984/000114 GB8400114W WO8402445A2 WO 1984002445 A2 WO1984002445 A2 WO 1984002445A2 GB 8400114 W GB8400114 W GB 8400114W WO 8402445 A2 WO8402445 A2 WO 8402445A2
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WO
WIPO (PCT)
Prior art keywords
composition
water
polymeric material
organic polymeric
volume
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Ceased
Application number
PCT/GB1984/000114
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French (fr)
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WO1984002445A3 (en
Inventor
James Hugh Raistrick
Stephen John Battersby
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Imperial Chemical Industries Ltd
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Imperial Chemical Industries Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Imperial Chemical Industries Ltd filed Critical Imperial Chemical Industries Ltd
Priority to EP84901597A priority Critical patent/EP0173685A1/en
Priority to AU28198/84A priority patent/AU2819884A/en
Priority to JP59501671A priority patent/JPS61501732A/en
Priority to PCT/GB1984/000114 priority patent/WO1984002445A2/en
Priority to US06/817,740 priority patent/US4719027A/en
Publication of WO1984002445A2 publication Critical patent/WO1984002445A2/en
Publication of WO1984002445A3 publication Critical patent/WO1984002445A3/en
Priority to NO854805A priority patent/NO854805L/en
Anticipated expiration legal-status Critical
Ceased legal-status Critical Current

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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F1/00Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties
    • H01F1/01Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials
    • H01F1/03Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity
    • H01F1/032Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of hard-magnetic materials
    • H01F1/10Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of hard-magnetic materials non-metallic substances, e.g. ferrites, e.g. [(Ba,Sr)O(Fe2O3)6] ferrites with hexagonal structure
    • H01F1/11Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of hard-magnetic materials non-metallic substances, e.g. ferrites, e.g. [(Ba,Sr)O(Fe2O3)6] ferrites with hexagonal structure in the form of particles
    • H01F1/113Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of hard-magnetic materials non-metallic substances, e.g. ferrites, e.g. [(Ba,Sr)O(Fe2O3)6] ferrites with hexagonal structure in the form of particles in a bonding agent

Definitions

  • This invention relates to a shaped article having magnetic properties, particularly to a shaped article comprising particulate material having magnetic properties, to a process for the production of said article, and to a composition for use in such production.
  • shaped article having magnetic properties, and particulate material having magnetic properties there are included articles and materials whose properties may be described as ferromagnetic or ferrimagnetic. Both these latter terms include articles and materials which once magnetised remain magnetised when removed from the influence of a magnetic field, and also articles and materials which are capable of being magnetised but which do not remain magnetised when removed from the influence of a magnetic field. Such articles and materials may be considered to be, respectively, permanently and temporarily magnetisable, and are frequently referred to as “hard” and “soft” respectively.
  • the metals iron, cobalt, and nickel are all ferromagnetic. They may be either permanently or temporarily magnetisable depending on the nature of or the amount of additional element or elements with which they may be alloyed. Materials which are ferrimagnetic include Ba
  • ferrimagnetic materials are examples of a class of materials referred to as ferrites.
  • the term ferrite is a term well known in the art.
  • Ferrites are magnetic oxides containing iron as a major metallic component and in addition another metal component, e.g. manganese, zinc, lead, strontium, barium, lithium or nickel.
  • the term can include spinels, perovskites, magnetoplumbites, and garnets.
  • Shaped articles of metals or alloys for example, iron, cobalt, and/or nickel and/or alloys thereof, may be made by conventional metal shaping techniques, for example, by powder compaction or by casting at high temperature.
  • the present invention relates to the production of shaped articles from particulate materials having magnetic properties, and although it may be applied to the production of shaped articles from metallic particulate magnetic materials, it is also suitable for use in the production of shaped articles from non-metallic particulate magnetic materials, for example ferrites, which may not normally be produced by metal shaping techniques.
  • Shaped articles of ferrites may be made, for example, by a powder compaction process in which the powdered ferrite is compacted under pressure in a suitably shaped mould and the powder is subsequently sintered by heating at a high temperature which may be in excess of 1200oC. Controlled heating and cooling rates may be required, as may be heating for some hours at the peak temperature. The presence of air or air enriched with oxygen may also be required. Shaped articles of ferrites may be made from a composition comprising, ferrite powder and a solution of a polymer binder. The article may be shaped, for example, by extrusion, injection moulding, or compression moulding, pyrolysi ⁇ g the polymer binder and finally sintering the ferrite powder.
  • Shaped articles of ferrites may also be made by filling of plastics materials, although in this case the article generally contains a relatively low proportion of ferrite and thus possesses relatively poor magnetic properties.
  • Permanently magnetisable materials are used in wide variety of applications, for example, in motors and in loud speakers. Temporarily magnetisable materials are used in transformers, in antennae rods, in recording heads and in memory cores. Furthermore, certain ferrites possess the unusual feature of being able to damp vibrations. Articles made in the manner described later may have a good combination of high modulus and good vibration damping.
  • the present invention relates to shaped articles of particulate materials having magnetic properties, and to the production of such articles by a process which does not involve a lengthy and expensive sintaring step, and which contain a high volume proportion of the particulate material.
  • a process for the production of a shaped article of a particulate material having magnetic properties which method comprises shaping a homogeneous mixture of
  • the particulate material having magnetic properties will generally be referred to hereinafter as the particulate material.
  • the components thereof should be thoroughly mixed so as to form a homogeneous mixture.
  • the components of the composition are preferably mixed under conditions of high shear, for example in a bladed high shear mixer.
  • a composition so formed may be further mixed under conditions of high shear by passing the composition repeatedly through the nip between a pair of rollers which may be rotating at the same or at different peripheral speeds.
  • the mixing may be effected at elevated temperature in order, for example, to reduce the viscosity of the composition and thus aid the mixing.
  • the elevated temperature should not be such as to result in premature drying of the composition by loss of water nor in excessive loss of water from the composition by evaporation.
  • the homogeneous composition of the invention may be shaped by a variety of techniques, depending on the consistency of the composition.
  • the composition comprises a relatively large proportion of water in the range up to 60% by volume of the composition the composition may be sufficiently fluid as to be capable of being cast in a suitably shaped mould.
  • the composition of the invention may contain a proportion of water, e.g. up to 30% by volume, such that the composition has a dough-like consistency, and the composition may be shaped by techniques known in the plastics or rubber processing art. For example, where the composition has a dough-like consistency it may be shaped by extrusion, e.g. into a rod or tube shape or by injection moulding into a desired shape, or it may be calendered to produce a sheet-like form. The composition may also be shaped by compression moulding of the composition in a suitably shaped mould.
  • compositions having a dough-like consistency are preferred as it is generally possible to use plastics or rubber processing equipment with such compositions, such compositions generally contain a relatively low proportion of water and thus there is a reduced amount of water to remove from the composition, and the shaped articles produced from such compositions are generally of higher flexural strength.
  • the temperature at which shaping of the composition may be effected may depend on the nature of the components of the composition and their relative proportions. Where the composition is to be shaped under relatively high pressure the composition may be shaped at or near ambient temperature. However, we have found that, particulary where the composition has the characteristics of a thermoplastic, it may be desirable, or even necessary, in order to readily effect the shaping process, to use an elevated temperature in order effectively to shape the composition. A suitably elevated temperature may be chosen by means of simple experiment.
  • water is removed from the shaped composition, that is it is dried. Drying may be effected merely by allowing the water to evaporate. However, in order to speed up the drying process it is preferred to dry the shaped composition at elevated temperature, for example at a temperature greater than 50oC. A temperature of 100oC or greater may be used. However, the elevated temperature, and the length of time at the elevated temperature, should not be such as to result in substantial reduction in the strength of the shaped article, which may be brought about, for example, by degradation of the polymeric material at elevated temperature.
  • the shaped article of the invention may have a high flexural strength, for example, a flexural strength in excess of 40 MPa.
  • the shaped article may have a flexural strength in excess of 100 MPa.
  • the shaped article comprises an organic polymeric material which is water-soluble or waterdispersible the article will be sensitive to water. Indeed, it may lose dimensional stability when contacted with water, particularly when soaked in water, and in a preferred embodiment of the invention the composition also comprises at least one additive which is capable of reacting with the polymeric material to insolubilise the material with respect to water. Use of such an additive substantially increases the dimensional stability of the shaped article when the article is contacted with water.
  • the final step of the process for the production of the shaped article comprises drying of the shaped composition to remove the water from the composition and reacting the additive with the organic polymeric material in order to insolubilise the latter material with respect to water.
  • this final step is referred to as setting.
  • Setting of the shaped composition may be effected at or near ambient temperature or it may be effected at elevated temperature, for example at a temperature in excess of 50oC. A temperature of up to 100°C or even greater may be used. Elevated temperatures may be desirable in order to initiate reaction of the additive with the organic polymeric material, or at least to increase the rate of this reaction. The elevated temperature, and the length of time at such elevated temperature should not be such as to result in substantial reduction in the strength of the product.
  • the components of the composition of the invention are selected such that a test composition comprising 63% by volume of particulate material, 7% by volume of water-soluble or water-dispersible organic polymeric material and 30% by volume of water, when extruded in a capillary rheometer at an extrusion pressure up to a maximum of 500 atmospheres undergoes and increase of at least 25%, and preferably at least 50%, in shear stress when a ten-fold increase in the shear rate of the test composition is effected when the shear rates as measured are within the range 0.1 to 5 second -1 .
  • a capillary rheometer in which the test composition is extruded comprises a piston in a cylindrical barrel and a capillary orifice through which the test composition may be extruded.
  • the shear stress in kN cm -2 is defined by and the shear rate in second -1 by where D is the diameter of the barrel of the rheometer in cm, v is the rate of travel of the piston in the barrel of the rheometer in cm min -1 , d is the diameter of the capillary of the rheometer in cm, L is the length of the capillary of the rheometer in cm, and F is the force in kN applied to the piston of the rheometer.
  • D will be in the range 1 to 3 cm
  • d in the range 0.2 to 0.5 cm
  • L in the range 5d to 20d.
  • the particulate material in the test composition should not be of a size so great nor of such a shape that the particulate material itself inhibits passage of the composition through the capillary of the rheometer.
  • particulate material having a size which results in a readily extrudable composition will be chosen, and a size in the range 10 to 100 microns will generally be suitable.
  • the composition, and shaped article, of the invention are not limited to particulate material having a size in this range.
  • a shaped article produced from the composition of the invention will be of higher flexural strength where the particulate material and organic polymeric material together are selected so that the test composition satisfies the aforementioned criteria of the capillary rheometer test than is the case where the particulate material and the organic polymeric material selected are such the the test composition does not satisfy the aformentioned criteria.
  • a shaped article produced from a composition containing these materials will have a flexural strength higher than that of (1) a shaped article produced from a composition containing the same organic polymeric material and a different particulate material which in combination do not satisfy the criteria of the capillary rheometer test, and
  • test composition Suitable combinations of particulate material and organic polymeric material which in the test composition satisfy the aforementioned capillary rheometer test will be disclosed hereinafter.
  • test composition for use in the capillary rheometer test should of course be thoroughly mixed and be sufficiently fluid that the composition itself is capable of being extruded in the capillary rheometer.
  • the test composition should have sufficient fluidity that shear rates in the range of 0.1 to 5 second -1 are obtained it may be necessary to carry out the test at elevated temperature, for example at a temperature greater than 50oC, e.g. at about 80oC.
  • composition of the invention is not of course limited to use of a material of the selected molecular weight.
  • the molecular weight is merely selected for the purposes of the test.
  • not more than 2%, and more preferably not more than 0.5%, of the total volume of the article comprises pores having a maximum dimension exceeding 100 microns, preferably 50 microns, and more preferably 15 microns, as measured by the method of quantitative microscopy.
  • These pore size criteria do not include pores which may be present in the particulate material, for example, where the particulate material comprises hollow particles.
  • Quantitative microscopy is a technique well known in the art. A surface of a sample of the shaped article is polished to produce a plane surface on the sample, the sample is washed to remove the polishing debris from the surface, and the surface is illuminated to ensure that the holes in the surface are contrasted with the plane parts of the surface, and the surface is viewed by means of an optical microscope, typically at a magnification of x100, and the holes exceeding 100 microns, or 50 microns or 15 microns in size, are determined, as described in "Quantitative Microscopy" by De Hoff and Rhines, McGraw Hill 1968.
  • Sufficient area of the surface of the sample should be viewed to reduce the statistical error, and usually, 1000 holes are counted.
  • the sample is then subjected to further polishing in order to expose another surface and the optical examination is repeated. In general, ten such surfaces are examined.
  • the total volume of pores in the shaped article expressed as a proportion of the apparent volume of the article, including the pores, does not exceed 20%. Porosities not exceeding 15%, and even porosities not exceeding 10% are more preferred. The porosity may even be less than 2%. These porosity criteria exclude pores which may be present in the particulate material, for example, where the particulate material comprises hollow particles.
  • Low porosity is a feature of shaped articles produced from compositions in which the organic polymeric material and the particulate material are selected so as to satisfy the criteria of the capillary rheometer test.
  • the particulate material is insoluble in water and is substantially unreactive with water, although we do not exclude use of particulate material which may be very slightly reactive with water.
  • the dimensions of the particles of the particulate material may vary over a broad range. Where the particulate material has a small size, however, undesirably large proportions of water may be required in order to produce a composition which is readily shapeable, and for this reason it is preferred, although not essential, that the median particle size is greater than 0.3 micron, more preferably greater than 3 microns.
  • the particulate material may comprise a plurality of particle sizes.
  • the particulate material may comprise a first fraction and a second fraction of size less than that of the first fraction. The use of such a plurality of particle sizes results in good packing of particles in the product and also may lead to a reduction in the proportion or organic polymeric material which otherwise may be required. Mixtures of different particulate materials having magnetic properties may be used.
  • the particulate material having magnetic properties may be for example a metal or alloy, e.g. iron, nickel, and/or cobalt, and/or alloys thereof. Shaped articles made of ferrites have a wide variety of applications, and for this reason the particulate material having magnetic properties may suitably be a ferrite.
  • Ferrites are magnetic oxides containing iron as a major metallic component and in addition another metal component.
  • the other metal component may be, for example, manganese, zinc, lead, strontium, barium, lithium or nickel.
  • ferrites include (Mn, Zn) Fe 2 O 4 , BaFe 12 O 19 , MnFe 2 O 4 and (Ni, Zn) Fe 2 O 4 .
  • position, and the shaped article produced therefrom may comprise particulate material other than a particulate material having magnetic properties.
  • the composition, and the shaped article produced therefrom may include fibrous material. Although the fibrous material may be in the form of random, chopped fibre, difficulty may be experienced in incorporating such fibrous material into the composition. For this reason the fibrous material is preferably in the form of a mat, which may be woven or non-woven. The mat may be pressed into the composition of the invention, or it may be formed in situ, e.g. by filament winding.
  • the particulate material may be present in the composition of the invention in a proportion of 40 to 90% by volume. It is preferred to use a relatively high proportion of particulate material, for example a proportion in the range 60 to 90% by volume.
  • compositions may contain a relatively low proportion of organic polymeric material, which material will generally be inflammable, and it is thus of advantage that the shaped article of the invention contains a relatively low proportion of such material.
  • compositions containing a high proportion of particulate material will generally contain a relatively low proportion of water. This is of advantage as there is then a lower proportion of water to remove from the composition during production of the shaped article.
  • the organic polymeric material in the composition of the invention should be water-soluble or water-dispersible. The function of the organic polymeric material is to aid in the processing of the composition, e.g. to aid in the production of a composition which is readily shaped, e.g.
  • the organic polymeric material is soluble in water, rather than waterdispersible, and. that the polymeric material is filmforming and contains groups, for example, hydroxyl or carboxylic acid groups, which have an affinity for the particulate material.
  • organic polymeric materials include hydroxy propyl methyl cellulose, polyethylene oxide, polyethylene glycol, polyacrylamide, and polyacrylic acid.
  • a particularly preferred organic polymeric material which, with a number of different particulate materials having magnetic properties in the form of a test composition satisfies the criteria of the aforementioned capillary rheometer test, is a hydrolysed polymer or copolymer of a vinyl ester, e.g. a hydrolysed vinyl acetate polymer or copolymer.
  • the polymer may be a copolymer of vinyl acetate and a monomer copolymerisable therewith, but it is preferably a hydrolysed poly(vinyl acetate).
  • the degree of hydrolysis of the vinyl acetate (co)polymer has a bearing on whether or net the
  • the degree of hydrolysis of the vinyl acetate (co)polymer be at least 50% but not more than 97%, and more preferably in the range 70 to 90%, that is, it is preferred that at least 50% but not more than 97%, and more preferably 70% to 90% of the vinyl acetate units in the polymer or copolymer, are hydrolysed to the alcohol form.
  • the properties of the shaped article produced therefrom are relatively insensitive to variations in the molecular weight of the hydrolysed vinyl acetate (co)polymer.
  • the molecular weight of the hydrolysed vinyl acetate (co)polymer will be at leat 3000, e.g. in the range 5000 to 125,000.
  • Such (co)polymers are readily available.
  • the (co)polymer may have a higher molecular weight.
  • In the composition of the invention there is present 2 to 25% of organic polymeric material by volume of the composition.
  • the ease of shaping of the composition generally improves with increase in the proportion of polymeric material in the composition, and a proportion of at least 7% by volume is preferred.
  • the polymeric material is generally capable of burning a proportion of not more than 20% by volume of polymeric material is preferred.
  • the proportion of water in the composition has an effect on the properties of the shaped article produced from the composition.
  • the composition In order to produce an article of particularly high flexural strength the composition should contain no more than 30% by volume of water. It is preferred to use as low a proportion of water as possible consistent with producing a composition which is shapeable. We prefer to use less than 20% by volume of water. In general it will be found necessary to use at least 5% be volume of water. However, a proportion of water may be used in the composition which is greater than that which would result in production of a very high strength article and some strength may be sacrificied in order to produce a composition which is more readily shaped.
  • the composition may suitably comprise a gelling agent for the organic polymeric material, that is a compound which forms labile bonds with the organic polymeric material.
  • a gelling agent for the organic polymeric material that is a compound which forms labile bonds with the organic polymeric material.
  • An alternative way of achieving high green strength in the composition is to include in the composition a proportion of an organic polymeric material which is soluble in the water of the composition at elevated temperature but which forms a gel at low temperature, e.g. at or near ambient temperature.
  • the composition may also comprise a proportion of a substantially fully hydrolysed poly(vinyl acetate) which is soluble in the water of the composition at elevated temperature but which forms a gel at ambient temperature.
  • the composition comprises an additive capable of reacting with the organic polymeric material to insolubilise the material with respect to water.
  • an additive capable of reacting with the organic polymeric material to insolubilise the material with respect to water.
  • the nature of this additive will depend on the particular organic polymeric material in the composition.
  • the additive may be a material reactive with the functional groups under the conditions used in forming the shaped article of the invention from the composition.
  • the insolubilisation of the organic polymeric material with respect to water may be achieved by cross-linking of the material.
  • the additive may be a compound of a polyvalent metal capable of reacting with the hydroxyl groups.
  • suitable compounds of a polyvalent metal include compounds of aluminium, Al 2 (OH) 5 NO 3 , and Al 2 (OH) 5 halide, for example, Al 2 (OH) 5 C1.
  • Other examples of compounds of a polyvalent metal include Zr (OH) 2 Cl 2 , (NH 4 ) 2 Cr 2 O 7 and Cr(OH) 1.8 (NO 3 ) 1.2 .
  • Selection of suitable combinations of watersoluble or water-dispersible organic polymeric materials and insolubilising additives may be made by reacting mixtures of such materials and additives and testing the product of reaction for water insolubility.
  • the additive in the composition is reacted with the polymeric material to insolubilise the material and water is removed from the composition.
  • the additive is a polyvalent metal compound reaction is suitably effected at elevated temperature.
  • the temperature may be greater than 100oC, which temperature serves to remove the water in the composition.
  • a temperature of, for example, up to 250oC may be used.
  • the polymeric material comprises a plurality of hydroxyl groups
  • the additive capable of reacting with the polymeric material to insolubilise the material with respect to water may itself be an organic compound reactive with the hydroxyl groups, for example, a dialdehyde, e.g. glyoxal.
  • a suitable reaction temperature is ambient temperature.
  • elevated temperatures are suitably used, e.g. up. to about 100oC, in order to remove the water from the composition and to accelerate the reaction.
  • the proportion of additive capable of reacting with the polymeric material will depend on the particular organic polymeric material and the particular additive in the composition.
  • the composition will contain a proportion of additive in the range 5 to 100% by volume of the organic polymeric material in the composition e.g. 10 to 50% by volume. It is preferred to select a proportion of additive which is sufficient not merely to insolublise the organic polymeric material with respect to water but which reacts with the polymeric material to produce a polymeric product which swells at most only to a limited extent in water, for example, which takes up not more than 50% by weight of water when the product of reaction of the organic polymeric material and the insolubilising additive is soaked in water. Suitable proportions may be selected by test on mixtures of organic polymeric material and insolubilising additive.
  • the composition of the invention also comprises an additive capable of effecting coupling between the polymeric material and the surface of the particulate material having magnetic properties in the composition.
  • an additive capable of effecting coupling between the polymeric material and the surface of the particulate material having magnetic properties in the composition.
  • shaped articles having high flexural strength. may be produced from compositons which do not contain such an additive capable of effecting coupling it has been found that such articles may suffer a substantial loss in flexural modulus when contacted with water.
  • the composition from which the shaped article is produced contains such an additive capable of effecting coupling the loss of flexural modulus of the article when the article is contacted with water, if any, is very much reduced.
  • the coupling additive which may suitably be used in a composition will depend on the nature of the particulate material and the organic polymeric material in the composition.
  • the additive capable of insolubilising the organic polymeric material be the same as the additive capable of effecting coupling between the polymeric material and the particulate material.
  • the additive capable of reacting with the organic polymeric material to insolubilise the latter with respect to water is a polyvalent metal compound
  • certain of the latter compounds are also capable of effecting coupling betweeen ferrite particulate materials and the organic polymeric material.
  • Suitable additive to fulfil both these functions include Al 2 (0H) 5 CL, (NH 4 )2 Cr 2 O 7 , Cr
  • the additive capable of effecting coupling when different from the additive capable of reacting with the organic polymeric material to insolublise the latter material with respect to water will be present in the composition in a relatively low proportion, although the proportion required may depend on the particle size of the particulate material.
  • the additive may be present in a proportion of 0.01 to 3% by volume of the particulate material in the composition.
  • the invention is illustrated by the following examples in which all parts are parts by volume, unless otherwise stated. Example 1
  • the crumble was then charged to a twin-roll mill the rollers of which were heated to a temperature of 70oC and the crumble was formed into sheet on the mill. the sheet being passed repeatedly through the nip between the rolls. The milling was continued for 5 minutes during which time some of the water evaporated, and the resultant sheet was removed from the mill.
  • the sheet contained 128 parts of particulate ferrite, 22.8 parts of hydrolysed poly(vinyl acetate),10 parts of aluminium hydroxy chloride, 4 parts of resorcinol, and 45 parts of water.
  • the sheet was then placed between two sheets of polyethylene terephthalate the faces of which were coated with mould release agent and the sheet was pressed in a hydraulic press at a temperature of 80oC and a pressure of 10 MPa for 10 minutes.
  • the platens of the press were then cooled by flowing cold water through the platens, the sheet was removed from the press, and the sheets of polyethylene terephthalate were removed from the sheet.
  • the sheet had a flexural strength of 112.6 MPa and a flexural modulus of 48.3 GPa, and contained 78% by volume of ferrite.
  • the sheet had the following magnetic properties.
  • Example 1 The mixing, shaping, and setting procedure of Example 1 was repeated on a composition comprising (Mn, Zn) ferrite 150 micron mean size 669.6 parts (Mn, Zn) ferrite 1 micron mean size 224.1 parts Hydrolysed poly(vinyl acetate)
  • the sheet which contained 83% by volume of ferrite, had a flexural strength of 106 MPa and a flexural modulus of 44.7 GPa.
  • the sheet had the following magnetic properties Remenance 355 gauss
  • the sheet which was produced contained 61% by volume of ferrite and had a low f ield permeability, measured as described in Example 2, of 7.2.

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Abstract

A shapeable composition comprising a homogeneous mixture of (a) at least one particulate ferrite material having magnetic properties, (b) at least one water-soluble or water-dispersible organic polymeric material, and (c) water, in the composition the components (a), (b) and (c) being present in a proportion by volume of the composition of respectively, 40 to 90%, 2 to 25%, and not more than 60%, a product produced therefrom, and a process for producing said product by removing water from the composition. The composition optionally contains an additive capable of insolubilising the organic polymeric material with respect to water.

Description

ARTICLE HAVING MAGNETIC PROPERTIES AND PRODUCTION THEREOF
This invention relates to a shaped article having magnetic properties, particularly to a shaped article comprising particulate material having magnetic properties, to a process for the production of said article, and to a composition for use in such production.
Within the scope of the terms shaped article having magnetic properties, and particulate material having magnetic properties, there are included articles and materials whose properties may be described as ferromagnetic or ferrimagnetic. Both these latter terms include articles and materials which once magnetised remain magnetised when removed from the influence of a magnetic field, and also articles and materials which are capable of being magnetised but which do not remain magnetised when removed from the influence of a magnetic field. Such articles and materials may be considered to be, respectively, permanently and temporarily magnetisable, and are frequently referred to as "hard" and "soft" respectively. The metals iron, cobalt, and nickel are all ferromagnetic. They may be either permanently or temporarily magnetisable depending on the nature of or the amount of additional element or elements with which they may be alloyed. Materials which are ferrimagnetic include Ba
Fe6 O19, which is permanently magnetisable, and (Mn, Zn) Fe2O4, which is temporarily magnetisable. Such examples of ferrimagnetic materials are examples of a class of materials referred to as ferrites. The term ferrite is a term well known in the art. Ferrites are magnetic oxides containing iron as a major metallic component and in addition another metal component, e.g. manganese, zinc, lead, strontium, barium, lithium or nickel. The term can include spinels, perovskites, magnetoplumbites, and garnets.
Shaped articles of metals or alloys, for example, iron, cobalt, and/or nickel and/or alloys thereof, may be made by conventional metal shaping techniques, for example, by powder compaction or by casting at high temperature. The present invention relates to the production of shaped articles from particulate materials having magnetic properties, and although it may be applied to the production of shaped articles from metallic particulate magnetic materials, it is also suitable for use in the production of shaped articles from non-metallic particulate magnetic materials, for example ferrites, which may not normally be produced by metal shaping techniques. Shaped articles of ferrites may be made, for example, by a powder compaction process in which the powdered ferrite is compacted under pressure in a suitably shaped mould and the powder is subsequently sintered by heating at a high temperature which may be in excess of 1200ºC. Controlled heating and cooling rates may be required, as may be heating for some hours at the peak temperature. The presence of air or air enriched with oxygen may also be required. Shaped articles of ferrites may be made from a composition comprising, ferrite powder and a solution of a polymer binder. The article may be shaped, for example, by extrusion, injection moulding, or compression moulding, pyrolysiπg the polymer binder and finally sintering the ferrite powder.
Shaped articles of ferrites may also be made by filling of plastics materials, although in this case the article generally contains a relatively low proportion of ferrite and thus possesses relatively poor magnetic properties.
Permanently magnetisable materials are used in wide variety of applications, for example, in motors and in loud speakers. Temporarily magnetisable materials are used in transformers, in antennae rods, in recording heads and in memory cores. Furthermore, certain ferrites possess the unusual feature of being able to damp vibrations. Articles made in the manner described later may have a good combination of high modulus and good vibration damping.
The present invention relates to shaped articles of particulate materials having magnetic properties, and to the production of such articles by a process which does not involve a lengthy and expensive sintaring step, and which contain a high volume proportion of the particulate material.
According to the present invention there is provided a process for the production of a shaped article of a particulate material having magnetic properties which method comprises shaping a homogeneous mixture of
(a) at least one particulate material having magnetic properties,
( b) at least one water-soluble or water-dispe rsible organic polymeric material , and
( c) wate r, and removing water f rom the thus formed shaped article , in the composition the componen ts ( a ) , ( b) , and (c) being present in a proportion by volume of the composition of respectively , 40 to 90 % , 2 to 25 % , and not more than 60% . In a further embodiment of the present invention there is provided a shapeable composition comprising a homogeneous mixture of
(a) at least one particulate material having magnetic properties,
(b) at least one water-soluble or water-dispersible organic polymeric material, and
(c) water in the composition the components (a), (b) and (c) being present in proportions by volume of the composition of respectively 40 to 90%, 2 to 25%, and not more than 60%.
There is also provided a shaped article of a particulate material having magnetic properties produced by removing water from the composition hereinbefore described.
The particulate material having magnetic properties will generally be referred to hereinafter as the particulate material. In producing the shapeable composition the components thereof should be thoroughly mixed so as to form a homogeneous mixture.
For example, the components of the composition are preferably mixed under conditions of high shear, for example in a bladed high shear mixer. If desired, and where the composition has a suitable consistency, a composition so formed may be further mixed under conditions of high shear by passing the composition repeatedly through the nip between a pair of rollers which may be rotating at the same or at different peripheral speeds. The mixing may be effected at elevated temperature in order, for example, to reduce the viscosity of the composition and thus aid the mixing. However, the elevated temperature, should not be such as to result in premature drying of the composition by loss of water nor in excessive loss of water from the composition by evaporation.
The homogeneous composition of the invention may be shaped by a variety of techniques, depending on the consistency of the composition. Thus where the composition comprises a relatively large proportion of water in the range up to 60% by volume of the composition the composition may be sufficiently fluid as to be capable of being cast in a suitably shaped mould.
The composition of the invention may contain a proportion of water, e.g. up to 30% by volume, such that the composition has a dough-like consistency, and the composition may be shaped by techniques known in the plastics or rubber processing art. For example, where the composition has a dough-like consistency it may be shaped by extrusion, e.g. into a rod or tube shape or by injection moulding into a desired shape, or it may be calendered to produce a sheet-like form. The composition may also be shaped by compression moulding of the composition in a suitably shaped mould.
Compositions having a dough-like consistency are preferred as it is generally possible to use plastics or rubber processing equipment with such compositions, such compositions generally contain a relatively low proportion of water and thus there is a reduced amount of water to remove from the composition, and the shaped articles produced from such compositions are generally of higher flexural strength. The temperature at which shaping of the composition may be effected may depend on the nature of the components of the composition and their relative proportions. Where the composition is to be shaped under relatively high pressure the composition may be shaped at or near ambient temperature. However, we have found that, particulary where the composition has the characteristics of a thermoplastic, it may be desirable, or even necessary, in order to readily effect the shaping process, to use an elevated temperature in order effectively to shape the composition. A suitably elevated temperature may be chosen by means of simple experiment.
In the final step of the process for the production of the shaped article water is removed from the shaped composition, that is it is dried. Drying may be effected merely by allowing the water to evaporate. However, in order to speed up the drying process it is preferred to dry the shaped composition at elevated temperature, for example at a temperature greater than 50ºC. A temperature of 100ºC or greater may be used. However, the elevated temperature, and the length of time at the elevated temperature, should not be such as to result in substantial reduction in the strength of the shaped article, which may be brought about, for example, by degradation of the polymeric material at elevated temperature.
The shaped article of the invention may have a high flexural strength, for example, a flexural strength in excess of 40 MPa. The shaped article may have a flexural strength in excess of 100 MPa. As the shaped article comprises an organic polymeric material which is water-soluble or waterdispersible the article will be sensitive to water. Indeed, it may lose dimensional stability when contacted with water, particularly when soaked in water, and in a preferred embodiment of the invention the composition also comprises at least one additive which is capable of reacting with the polymeric material to insolubilise the material with respect to water. Use of such an additive substantially increases the dimensional stability of the shaped article when the article is contacted with water.
Where the composition contains such an additive the final step of the process for the production of the shaped article comprises drying of the shaped composition to remove the water from the composition and reacting the additive with the organic polymeric material in order to insolubilise the latter material with respect to water. In this case this final step is referred to as setting.
The conditions under which setting of the shaped composition may be effected will depend on the nature of the components of the composition, and in particular on the nature of the organic polymeric material and on the nature of the additive reactive therewith. Suitable conditions for use in effecting the setting reaction will be disclosed hereafter in respect of compositions containing specific organic polymeric materials and additives reactive therewith. Setting of the shaped composition may be effected at or near ambient temperature or it may be effected at elevated temperature, for example at a temperature in excess of 50ºC. A temperature of up to 100°C or even greater may be used. Elevated temperatures may be desirable in order to initiate reaction of the additive with the organic polymeric material, or at least to increase the rate of this reaction. The elevated temperature, and the length of time at such elevated temperature should not be such as to result in substantial reduction in the strength of the product.
Where particularly high flexural strength shaped articles are to be produced it is preferred that the components of the composition of the invention are selected such that a test composition comprising 63% by volume of particulate material, 7% by volume of water-soluble or water-dispersible organic polymeric material and 30% by volume of water, when extruded in a capillary rheometer at an extrusion pressure up to a maximum of 500 atmospheres undergoes and increase of at least 25%, and preferably at least 50%, in shear stress when a ten-fold increase in the shear rate of the test composition is effected when the shear rates as measured are within the range 0.1 to 5 second-1.
A capillary rheometer in which the test composition is extruded comprises a piston in a cylindrical barrel and a capillary orifice through which the test composition may be extruded. The shear stress in kN cm-2 is defined by
Figure imgf000011_0001
and the shear rate in second-1 by
Figure imgf000011_0002
where D is the diameter of the barrel of the rheometer in cm, v is the rate of travel of the piston in the barrel of the rheometer in cm min-1, d is the diameter of the capillary of the rheometer in cm, L is the length of the capillary of the rheometer in cm, and F is the force in kN applied to the piston of the rheometer. In general, D will be in the range 1 to 3 cm, d in the range 0.2 to 0.5 cm, and L in the range 5d to 20d.
The particulate material in the test composition should not be of a size so great nor of such a shape that the particulate material itself inhibits passage of the composition through the capillary of the rheometer. For use in the capillary rheometer test particulate material having a size which results in a readily extrudable composition will be chosen, and a size in the range 10 to 100 microns will generally be suitable. The composition, and shaped article, of the invention are not limited to particulate material having a size in this range.
A shaped article produced from the composition of the invention will be of higher flexural strength where the particulate material and organic polymeric material together are selected so that the test composition satisfies the aforementioned criteria of the capillary rheometer test than is the case where the particulate material and the organic polymeric material selected are such the the test composition does not satisfy the aformentioned criteria.
For example, where the organic polymeric material and the particulate material are selected so that the test composition satisfies the aforementioned criteria a shaped article produced from a composition containing these materials will have a flexural strength higher than that of (1) a shaped article produced from a composition containing the same organic polymeric material and a different particulate material which in combination do not satisfy the criteria of the capillary rheometer test, and
(2) a shaped article produced from a composition containing the same particulate material and a different organic polymeric material which in combination do not satisfy the criteria of the capillary rheometer test.
Suitable combinations of particulate material and organic polymeric material which in the test composition satisfy the aforementioned capillary rheometer test will be disclosed hereinafter. In general, the greater is the change in shear stress observed when the shear rate is increased tenfold the greater will be the flexural strength of the shaped article produced from the composition of the invention, and for this reason it is preferred that the test composition undergoes an increase of at least 75% in shear stress when a ten-fold increase in shear rate of the test composition is effected.
The test composition for use in the capillary rheometer test should of course be thoroughly mixed and be sufficiently fluid that the composition itself is capable of being extruded in the capillary rheometer. In order that the test composition should have sufficient fluidity that shear rates in the range of 0.1 to 5 second-1 are obtained it may be necessary to carry out the test at elevated temperature, for example at a temperature greater than 50ºC, e.g. at about 80ºC. On the other hand, it may be necessary, particularly where the test composition is of hihh fluidity, to carry out the capillary rheometer test at a temperature below ambient temperature. In effecting the extrusion the composition should not separate into its component parts, for example, water should not tend to separate from the composition.
In order to produce an extrudable composition it may be necessary to select a suitable molecular weight of organic polymeric material for use in the test composition. The composition of the invention is not of course limited to use of a material of the selected molecular weight. The molecular weight is merely selected for the purposes of the test.
For particularly high flexural strength shaped articles it is preferred that not more than 2%, and more preferably not more than 0.5%, of the total volume of the article comprises pores having a maximum dimension exceeding 100 microns, preferably 50 microns, and more preferably 15 microns, as measured by the method of quantitative microscopy. These pore size criteria do not include pores which may be present in the particulate material, for example, where the particulate material comprises hollow particles. The production of such a preferred shaped article is assisted by application of high shear during mixing of the composition, which may be effected in the substantial absence of air, for example, under vacuum and/or by application of at least a moderate pressure, e.g. an applied pressure of 1 to 5 MPa in the shaping step, particularly with a dough-like composition. Quantitative microscopy is a technique well known in the art. A surface of a sample of the shaped article is polished to produce a plane surface on the sample, the sample is washed to remove the polishing debris from the surface, and the surface is illuminated to ensure that the holes in the surface are contrasted with the plane parts of the surface, and the surface is viewed by means of an optical microscope, typically at a magnification of x100, and the holes exceeding 100 microns, or 50 microns or 15 microns in size, are determined, as described in "Quantitative Microscopy" by De Hoff and Rhines, McGraw Hill 1968. Sufficient area of the surface of the sample should be viewed to reduce the statistical error, and usually, 1000 holes are counted. The sample is then subjected to further polishing in order to expose another surface and the optical examination is repeated. In general, ten such surfaces are examined. It is also preferred, for additional improvements in flexural strength, that the total volume of pores in the shaped article expressed as a proportion of the apparent volume of the article, including the pores, does not exceed 20%. Porosities not exceeding 15%, and even porosities not exceeding 10% are more preferred. The porosity may even be less than 2%. These porosity criteria exclude pores which may be present in the particulate material, for example, where the particulate material comprises hollow particles.
Low porosity is a feature of shaped articles produced from compositions in which the organic polymeric material and the particulate material are selected so as to satisfy the criteria of the capillary rheometer test.
In the composition of the invention the particulate material is insoluble in water and is substantially unreactive with water, although we do not exclude use of particulate material which may be very slightly reactive with water. The dimensions of the particles of the particulate material may vary over a broad range. Where the particulate material has a small size, however, undesirably large proportions of water may be required in order to produce a composition which is readily shapeable, and for this reason it is preferred, although not essential, that the median particle size is greater than 0.3 micron, more preferably greater than 3 microns. The particulate material may comprise a plurality of particle sizes. For example, the particulate material may comprise a first fraction and a second fraction of size less than that of the first fraction. The use of such a plurality of particle sizes results in good packing of particles in the product and also may lead to a reduction in the proportion or organic polymeric material which otherwise may be required. Mixtures of different particulate materials having magnetic properties may be used.
The particulate material having magnetic properties may be for example a metal or alloy, e.g. iron, nickel, and/or cobalt, and/or alloys thereof. Shaped articles made of ferrites have a wide variety of applications, and for this reason the particulate material having magnetic properties may suitably be a ferrite.
Ferrites are magnetic oxides containing iron as a major metallic component and in addition another metal component. The other metal component may be, for example, manganese, zinc, lead, strontium, barium, lithium or nickel. Examples of ferrites include (Mn, Zn) Fe2O4, BaFe12O19, MnFe2O4 and (Ni, Zn) Fe2O4. Many other examples of ferrites are described in the art. position, and the shaped article produced therefrom, may comprise particulate material other than a particulate material having magnetic properties. The composition, and the shaped article produced therefrom, may include fibrous material. Although the fibrous material may be in the form of random, chopped fibre, difficulty may be experienced in incorporating such fibrous material into the composition. For this reason the fibrous material is preferably in the form of a mat, which may be woven or non-woven. The mat may be pressed into the composition of the invention, or it may be formed in situ, e.g. by filament winding.
The particulate material may be present in the composition of the invention in a proportion of 40 to 90% by volume. It is preferred to use a relatively high proportion of particulate material, for example a proportion in the range 60 to 90% by volume.
Such preferred compositions may contain a relatively low proportion of organic polymeric material, which material will generally be inflammable, and it is thus of advantage that the shaped article of the invention contains a relatively low proportion of such material. Also, compositions containing a high proportion of particulate material will generally contain a relatively low proportion of water. This is of advantage as there is then a lower proportion of water to remove from the composition during production of the shaped article. The organic polymeric material in the composition of the invention should be water-soluble or water-dispersible. The function of the organic polymeric material is to aid in the processing of the composition, e.g. to aid in the production of a composition which is readily shaped, e.g. a composition of dough-like consistency, and to provide shaperetaining properties to the shaped article of the invention. It is preferred that the organic polymeric material is soluble in water, rather than waterdispersible, and. that the polymeric material is filmforming and contains groups, for example, hydroxyl or carboxylic acid groups, which have an affinity for the particulate material.
Examples of organic polymeric materials include hydroxy propyl methyl cellulose, polyethylene oxide, polyethylene glycol, polyacrylamide, and polyacrylic acid. A particularly preferred organic polymeric material which, with a number of different particulate materials having magnetic properties in the form of a test composition satisfies the criteria of the aforementioned capillary rheometer test, is a hydrolysed polymer or copolymer of a vinyl ester, e.g. a hydrolysed vinyl acetate polymer or copolymer. The polymer may be a copolymer of vinyl acetate and a monomer copolymerisable therewith, but it is preferably a hydrolysed poly(vinyl acetate).
The degree of hydrolysis of the vinyl acetate (co)polymer has a bearing on whether or net the
(co)polymer in combination with a particulate material in the test composition satisfies the aforementioned criteria of the capillary rheometer test. In order that in the capillary rheometer test an increase of at least 25% in shear stress should be produced by the ten-fold increase in shear rate, it is preferred that the degree of hydrolysis of the vinyl acetate (co)polymer be at least 50% but not more than 97%, and more preferably in the range 70 to 90%, that is, it is preferred that at least 50% but not more than 97%, and more preferably 70% to 90% of the vinyl acetate units in the polymer or copolymer, are hydrolysed to the alcohol form. For a given proportion of hydrolysed vinyl acetate (co)polymer in the composition of the invention the properties of the shaped article produced therefrom are relatively insensitive to variations in the molecular weight of the hydrolysed vinyl acetate (co)polymer. In general, however, the molecular weight of the hydrolysed vinyl acetate (co)polymer will be at leat 3000, e.g. in the range 5000 to 125,000. Such (co)polymers are readily available. The (co)polymer may have a higher molecular weight. In the composition of the invention there is present 2 to 25% of organic polymeric material by volume of the composition. The ease of shaping of the composition generally improves with increase in the proportion of polymeric material in the composition, and a proportion of at least 7% by volume is preferred. On the other hand as the polymeric material is generally capable of burning a proportion of not more than 20% by volume of polymeric material is preferred.
The proportion of water in the composition has an effect on the properties of the shaped article produced from the composition. In order to produce an article of particularly high flexural strength the composition should contain no more than 30% by volume of water. It is preferred to use as low a proportion of water as possible consistent with producing a composition which is shapeable. We prefer to use less than 20% by volume of water. In general it will be found necessary to use at least 5% be volume of water. However, a proportion of water may be used in the composition which is greater than that which would result in production of a very high strength article and some strength may be sacrificied in order to produce a composition which is more readily shaped.
Where the high green strength is desired in the moulded composition of the invention, that is before setting of the composition, the composition may suitably comprise a gelling agent for the organic polymeric material, that is a compound which forms labile bonds with the organic polymeric material. An alternative way of achieving high green strength in the composition is to include in the composition a proportion of an organic polymeric material which is soluble in the water of the composition at elevated temperature but which forms a gel at low temperature, e.g. at or near ambient temperature. For example the composition may also comprise a proportion of a substantially fully hydrolysed poly(vinyl acetate) which is soluble in the water of the composition at elevated temperature but which forms a gel at ambient temperature.
It is a preferred feature of the invention that the composition comprises an additive capable of reacting with the organic polymeric material to insolubilise the material with respect to water. The nature of this additive will depend on the particular organic polymeric material in the composition.
Where the organic polymeric material comprises a plurality of reactive functional groups the additive may be a material reactive with the functional groups under the conditions used in forming the shaped article of the invention from the composition. In this case the insolubilisation of the organic polymeric material with respect to water may be achieved by cross-linking of the material. For example, where the polymeric material comprises a plurality of hydroxyl groups, e.g. as in a hydrolysed vinyl ester polymer or copolymer such as hydrolysed poly(vinyl acetate), the additive may be a compound of a polyvalent metal capable of reacting with the hydroxyl groups. Particular examples of suitable compounds of a polyvalent metal include compounds of aluminium, Al2(OH)5NO3, and Al2(OH)5 halide, for example, Al2(OH)5C1. Other examples of compounds of a polyvalent metal include Zr (OH)2 Cl2, (NH4)2Cr2O7 and Cr(OH)1.8(NO3)1.2.
Selection of suitable combinations of watersoluble or water-dispersible organic polymeric materials and insolubilising additives may be made by reacting mixtures of such materials and additives and testing the product of reaction for water insolubility.
In effecting setting of the composition comprising such an additive the additive in the composition is reacted with the polymeric material to insolubilise the material and water is removed from the composition. Where the additive is a polyvalent metal compound reaction is suitably effected at elevated temperature. For example, the temperature may be greater than 100ºC, which temperature serves to remove the water in the composition. A temperature of, for example, up to 250ºC may be used. Where the polymeric material comprises a plurality of hydroxyl groups the additive capable of reacting with the polymeric material to insolubilise the material with respect to water may itself be an organic compound reactive with the hydroxyl groups, for example, a dialdehyde, e.g. glyoxal.
In this case a suitable reaction temperature is ambient temperature. However, elevated temperatures are suitably used, e.g. up. to about 100ºC, in order to remove the water from the composition and to accelerate the reaction.
In the composition of the invention the proportion of additive capable of reacting with the polymeric material will depend on the particular organic polymeric material and the particular additive in the composition.
In general the composition will contain a proportion of additive in the range 5 to 100% by volume of the organic polymeric material in the composition e.g. 10 to 50% by volume. It is preferred to select a proportion of additive which is sufficient not merely to insolublise the organic polymeric material with respect to water but which reacts with the polymeric material to produce a polymeric product which swells at most only to a limited extent in water, for example, which takes up not more than 50% by weight of water when the product of reaction of the organic polymeric material and the insolubilising additive is soaked in water. Suitable proportions may be selected by test on mixtures of organic polymeric material and insolubilising additive.
In a particularly preferred embodiment of the invention the composition of the invention also comprises an additive capable of effecting coupling between the polymeric material and the surface of the particulate material having magnetic properties in the composition. Although shaped articles having high flexural strength.may be produced from compositons which do not contain such an additive capable of effecting coupling it has been found that such articles may suffer a substantial loss in flexural modulus when contacted with water. Where the composition from which the shaped article is produced contains such an additive capable of effecting coupling the loss of flexural modulus of the article when the article is contacted with water, if any, is very much reduced. The coupling additive which may suitably be used in a composition will depend on the nature of the particulate material and the organic polymeric material in the composition.
It is preferred that the additive capable of insolubilising the organic polymeric material be the same as the additive capable of effecting coupling between the polymeric material and the particulate material.
For example, where the additive capable of reacting with the organic polymeric material to insolubilise the latter with respect to water is a polyvalent metal compound certain of the latter compounds are also capable of effecting coupling betweeen ferrite particulate materials and the organic polymeric material. Suitable additive to fulfil both these functions include Al2(0H)5CL, (NH4)2 Cr2O7, Cr
(OH)1.8(NO3)1.2 and Al2 (OH)5 NO3. In general the additive capable of effecting coupling, when different from the additive capable of reacting with the organic polymeric material to insolublise the latter material with respect to water will be present in the composition in a relatively low proportion, although the proportion required may depend on the particle size of the particulate material. For example, the additive may be present in a proportion of 0.01 to 3% by volume of the particulate material in the composition. The invention is illustrated by the following examples in which all parts are parts by volume, unless otherwise stated. Example 1
128 parts of a particulate ferrite, BaFe12O19, having a particle size of 10 microns, and 22.8 parts of hydrolysed poly(vinyl acetate) (Gohsenol GH17S Nippon Gohsei, degree of hydrolysis 88% degree of polymerisation 2000) were thoroughly mixed in a bladed mixer. 4 parts of resorcinol in 15 parts of water were mixed with 40 parts of an aqueous solution containing 30 parts of water and 10 parts of aluminium hydroxy chloride containing 12.1% w/w A1, 8.75 % w/w C1, the latter solution having a viscosity of 18 cps, and the resultant solution added to the mixed solids in the bladed mixer to form a crumble.
The crumble was then charged to a twin-roll mill the rollers of which were heated to a temperature of 70ºC and the crumble was formed into sheet on the mill. the sheet being passed repeatedly through the nip between the rolls. The milling was continued for 5 minutes during which time some of the water evaporated, and the resultant sheet was removed from the mill.
The sheet contained 128 parts of particulate ferrite, 22.8 parts of hydrolysed poly(vinyl acetate),10 parts of aluminium hydroxy chloride, 4 parts of resorcinol, and 45 parts of water. The sheet was then placed between two sheets of polyethylene terephthalate the faces of which were coated with mould release agent and the sheet was pressed in a hydraulic press at a temperature of 80ºC and a pressure of 10 MPa for 10 minutes. The platens of the press were then cooled by flowing cold water through the platens, the sheet was removed from the press, and the sheets of polyethylene terephthalate were removed from the sheet.
Setting of the sheet was completed by placing the sheet between two flat pieces of wood, the sheet was allowed to stand for 1 day at 20ºC, it was then heated at 80ºC for 1 day, and finally it was heated at 180ºC for 1 hour.
The sheet had a flexural strength of 112.6 MPa and a flexural modulus of 48.3 GPa, and contained 78% by volume of ferrite.
The sheet had the following magnetic properties.
Remenance (Br) 1430 Gauss Coercivity (He) 750 Oersteds
BHmax product 0.30 x 106 gauss Oersteds saturation magnetisation 2720 gauss. Example 2
The mixing, shaping, and setting procedure of Example 1 was repeated on a composition comprising (Mn, Zn) ferrite 150 micron mean size 669.6 parts (Mn, Zn) ferrite 1 micron mean size 224.1 parts Hydrolysed poly(vinyl acetate)
Gohsenol GH 17S 115.8 parts
Polyviol VO3-140 (Wacker-Chemie) 21.0 parts degree of hydrolysis 86-89%, degree of polymerisation 300 Aluminium hydroxy chloride solution 203.3 parts (as used in Example 1)
Water 140 parts
The sheet, which contained 83% by volume of ferrite, had a flexural strength of 106 MPa and a flexural modulus of 44.7 GPa.
The sheet had the following magnetic properties Remenance 355 gauss
Coercivity (He) 9.85 Oersteds
Initial permeability 19.8 Maximum permeability 26.0
Saturation magnetisation 4480 gauss A ring was cut from the sheet and the low field permeability of the ring was measured by comparing the inductance of a coil wound on the ring with the theoretic inductance for an air-cored coil. The low field permeability was 19.1. Example 3
The mixing, shaping, and setting procedure of Examples was repeated on a composition comprising (Mn, Zn) ferrite 150 micron mean size 54.2 parts
(Mn, Zn) ferrite 1 micron mean size 18.1 parts Hydrolysed poly(vinyl acetate)
Gohsenol GH 17S 29.3 parts
Polyviol VO3-140 5.4 parts
Aluminium hydroxy chloride solution
(as used in Example 1) 42.7 parts
Water 14.3 parts
The sheet which was produced contained 61% by volume of ferrite and had a low f ield permeability, measured as described in Example 2, of 7.2.

Claims

1. A shapeable composition comprising a homogeneous mixture of
(a) at least one particulate ferrite material having magnetic properties,
(b) at least one water-soluble or water-dispersible organic polymeric material, and
(c) water, in the composition the components (a), (b) and (c) being present in a proportion by volume of the composition of respectively, 40 to 90%, 2 to 25%, and not more than 60%.
2. A shapeable composition as claimed Claim 1 characterised in that the particulate ferrite material having magnetic properties has a median particle size of greater than 0.3 micron.
3. A shapeable composition as claimed in Claim 1 or Claim 2 characterised in that the particulate ferrite material having magnetic properties comprises a plurality of particle sizes.
4. A shapeable composition as claimed in any one of Claims 1 to 3 characterised in that the composition comprises particulate ferrite material having magnetic properties in a proportion of 60% to 90% by volume.
5. A shapeable composition as claimed in any one of Claims 1 to 4 characterised in that the components of the composition are selected such that a test composition comprising 63% by volume of particulate ferrite material having magnetic properties, 7% by volume of water-soluble or water-dispersible organic polymeric material, and 30% by volume of water, when extruded in a capillary rheometer at an extrusion pressure up to a maximum of 500 atmospheres undergoes an increase of at least 25% in shear stress when a tenfold increase in the shear rate of the test composition is effected when the shear rates as measured are within the range 0.1 to 5 second-1.
6. A shapeable composition as claimed in any one of Claims 1 to 5 characterised in that the organic polymeric material comprises a hydrolysed polymer or copolymer of a vinyl ester.
7. A shapeable composition as claimed in Claim 6 characterised in that the organic polymeric material comprises hydrolysed poly(vinyl acetate).
8. A shapeable composition as claimed in any one of Claims 1 to 7 characterised in that the organic polymeric material is present in a proportion of 7% to 20% by volume.
9. A shapeable composition as claimed in any one of Claims 1 to 8 characterised in that the composition contains not more than 30% by volume of water.
10. A shapeable composition as claimed in Claim 8 characterised in that the composition contains 5% to 20% by volume of water.
11. A shapeable composition as claimed in any one of Claims 1 to 10 characterised in that the composition comprises an additive capable of reacting with the organic polymeric material to insolubilise the material with respect to water.
12. A shapeable composition as claimed in Claim 11 characterised in that the additive is aluminium hydroxy chloride.
13. A shapeable composition as claimed in Claim 11 or Claim 12 characterised in that the additive is present in a proportion of 5% to 100% by volume of the organic polymeric material in the composition.
14. A shapeable composition as claimed in any one of Claims 1 to 13 characterised in that the composition comprises an additive capable of effecting coupling between the organic polymeric material and the surface of the particulate ferrite material having magnetic properties.
15. A shapeable composition as claimed in Claim 14 characterised in that the additive capable of insolubilising the organic polymeric material is the same as the additive capable of effecting coupling.
16. A process for the production of a shaped article having magnetic properties which process comprises shaping a composition as claimed in any one of Claims 1 to 15, and removing water from the thus shaped composition.
17. A process as claimed in Claim 16 characterised in that the composition is shaped by calendering, injection moulding, compression moulding, or by extrusion.
18. A process as claimed in Claim 16 or Claim 17 characterised in that water is removed from the shaped composition by heating at a temperature of 100ºC or greater.
19. A process as claimed in any one of Claims 16 to 18 characterised in that water is removed from the shaped composition, and the additive capable of insolubilising the organic polymeric material with respect to water, when said additive is present, is reacted with said material by heating at a temperature of 100ºC or greater.
20. A shaped article of a particulate material having magnetic properties characterised in that said article is produced by removing water from a shaped composition as claimed in any one of Claims 1 to 15.
21. A shaped article as claimed in Claim 20 characterised in that there, is present an additive capable of insolubilising the organic polymeric material with respect to water, and in that said additive is reacted, with said material.
22. A shaped article as claimed in Claim 20 or Claim 21 characterised in that not more than 2% of the total volume of said article comprises pores having a maximum dimension exceeding 100 microns.
23. A shaped article as claimed in Claim 22 characterised in that not more than 0.5% of the total volume of said article comprises pores having a maximum dimension exceeding 15 microns.
24. A shaped article as claimed in any one of Claims 20 to 23 characterised in that the total volume of pores in the shaped article does not exceed 20%.
PCT/GB1984/000114 1984-04-02 1984-04-02 Article having magnetic properties and production thereof Ceased WO1984002445A2 (en)

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AU28198/84A AU2819884A (en) 1984-04-02 1984-04-02 Article having magnetic properties and production thereof
JP59501671A JPS61501732A (en) 1984-04-02 1984-04-02 Magnetic articles and their manufacture
PCT/GB1984/000114 WO1984002445A2 (en) 1984-04-02 1984-04-02 Article having magnetic properties and production thereof
US06/817,740 US4719027A (en) 1984-04-02 1984-04-02 Article having magnetic properties and production thereof
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EP (1) EP0173685A1 (en)
JP (1) JPS61501732A (en)
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GB2322378B (en) * 1995-11-15 2000-11-29 Thueringisches Inst Textil Process for producing sensor material

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EP0173685A1 (en) 1986-03-12
NO854805L (en) 1985-11-29
US4719027A (en) 1988-01-12
WO1984002445A3 (en) 1985-01-31
JPS61501732A (en) 1986-08-14
AU2819884A (en) 1984-07-17

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