FR2830545A1 - Paper sensitive to external magnetic fields, useful for making banknotes or jigsaw puzzles, comprises magnetizable particles distributed within the paper - Google Patents

Abstract

Paper sensitive to external magnetic fields comprises magnetizable particles distributed within the paper. Independent claims are also included for: (1) production of paper as above by mixing paper pulp with magnetizable particles and optionally a dispersant and dewatering the pulp; (2) an article comprising paper as above.

Description

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 The present invention relates to a paper sensitive to external magnetic fields comprising magnetizable particles distributed in the mass of the paper, a method of preparation and articles comprising such a paper.

THE STATE OF THE ART
Numerous documents of the prior art are known, describing paper articles or sheets of magnetic paper intended for different uses.

 Thus, US Patent 4,258,920 (Waldron et al.) Describes puzzles comprising magnetic paper pieces comprising 1 to 10% by weight of iron filings.

 US Pat. No. 4,234,378 (Iwasaki et al.) Describes a process for the manufacture of sheets of magnetic paper containing 70 to 90% by weight of ferrous powder, of the plumbite barium and plumbite strontium type, consisting of primary particles of 0, 1 to 2 m and secondary particles less than 20 m.

 Patent application JP1207496 (Tohoku Metal Ind Ltd) describes wall charts obtained by dispersing magnetic particles on which magnetic notices may be available.

 However, these articles and the papers from which they are made have the disadvantage of always remaining magnetic and of magnetizing them so that they are very difficult to handle.

 Thus, magnetic and magnetized puzzle pieces all remain agglomerated together so that the player has great difficulty in selecting a particular puzzle piece.

 In addition, these papers based on magnetic particles are expensive to manufacture.

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THE INVENTION
The Applicant has developed a new paper which is magnetically inert in itself, but which is sensitive to external magnetic fields.

 Such paper is not magnetic in itself. However, it is capable of reacting to an external magnetic field, for example produced by a magnet. This paper thus avoids the drawbacks mentioned above. Such paper can be produced from recovered material which makes it possible to produce it at low cost.

 In addition, the paper sensitive to magnetic fields of the invention can be calibrated so as to respond to a specific magnetic field. Thus, this paper can be easily and quickly characterized and identified when it is subjected to the influence of a magnetic field whose field lines cross, for example, the sheet of paper.

 The present invention also relates to a method of manufacturing a paper sensitive to external magnetic fields as well as articles based on such papers consisting in particular of puzzle pieces or banknotes.

 The present invention therefore has for first object a paper sensitive to external magnetic fields comprising magnetizable particles distributed in the mass of the paper.

 The term “magnetizable particles” means particles composed in particular of one or more metals. These particles are not magnetic in themselves, that is to say that on the macroscopic scale they do not generate a magnetic field.

 Preferably, the paper according to the invention also contains at least one dispersing agent.

 The dispersing agent, even if it is not compulsory, promotes the homogeneous distribution of the magnetizable particles in the mass of paper. It makes it possible to minimize the agglomeration of the magnetizable particles between them.

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 Preferably, the magnetizable particles can be distributed homogeneously in the mass of the paper. These particles can also be distributed over at least one of the surfaces of the paper or else over a predetermined part of the paper.

 The homogeneous distribution of the magnetizable particles in the mass of the paper can be observed, for example, in optical microscopy or in electron microscopy by exploiting the signal due to the backscattered electrons of the magnetizable particles. The homogeneous distribution of the magnetizable particles in the mass of the paper can be determined statistically by evaluating a proportion of magnetizable particles per unit of surface observed and / or a distribution in the thickness of the paper.

 Magnetizable particles can be obtained from the waste of developers of xerographic engines such as those from laser printers and photocopiers. This developer waste can come, for example, from devices sold by the companies Xeikon, Agfa, Xerox, Man Roland, IBM, Barco and Nielpeters.

 This developer waste is usually composed of small particles of toner, having a size between 6 and 10 m, agglomerated with large particles, having a size between 30 and 60 pu.

The latter have the function of transporting small particles of toner.

 The large particles of xerographic engine developers can be used as magnetizable particles according to the invention.

 It is possible to separate the two types of particles by suspension in water, then the action of a flow in the presence of a magnetic field. It is sometimes not necessary to separate these two types of particles because during the production of paper, small toner particles can be removed in the drip water.

 Magnetizable particles from xerographic engine developers have many advantages: they are inexpensive (in the form of waste) and they are stainless. They can therefore be used for the production of paper according to the invention.

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 The chemical composition of magnetizable particles from developers of xerographic engines is well known and consists, for the most part, of an iron-based material. A study of the X-ray micro-analysis spectrum has made it possible to determine that particles of particularly advantageous developers are composed of a material comprising iron, oxygen, copper and zinc.

 An X-ray micro-analysis spectrum corresponds to an energy selection spectrum (or EDX energy dispersion) of X-ray signals emitted by the material subjected to the excitation of an electron beam. Each photon X, resulting from the de-excitation of an atom, which enters the diode "Si-Li" of detection will ionize a silicon atom by photoelectric effect which, in turn, will generate a number of pairs "electrons- holes "in proportion to the energy of the incident photon. Thus, under the action of an electric field of reverse polarization of the diode, each photon creates a relatively weak electric pulse which must be amplified. The multichannel analyzer provides information proportional to the amplitude of the pulse which defines the rank of the channel into which it will be classified.

 The micro-analysis spectrum X of the waste particles from xerographic engines, comprising the magnetizable particles and the toner particles, is represented in FIG. 1. The abscissa and the ordinate of this spectrum are respectively the energy of the photon and the number of strokes (number of elements present in an energy channel).

 It has been possible to determine that the preferred magnetizable particles according to the invention can advantageously consist of a material comprising from 60 to 90% of iron, 30 to 40% of oxygen, 10 to 20% of zinc and 0 to 10 % copper, in atomic percentage. The magnetizable particles can also include carbon and / or silicon.

 It is also possible to use as magnetizable particles microspheres of stainless steel such as stainless steel.

 The magnetizable particles can have an average size of between 20 and 60 μm, preferably between 40 and 50 μm, even more preferably of 45 μm.

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 When the magnetizable particles are developer particles, it may be necessary to mechanically reduce their sizes so as to obtain the desired average size.

 The weight of the magnetizable particles can be between 2 and 75%, preferably between 10 and 40% relative to the total weight of the paper. The ratio considered is established by dry weight of residual material.

 The weight of dispersing agent can be between 0.05 and 2%, preferably between 1 and 1.5%, relative to the total weight of the paper. The ratio considered is established by dry weight of residual material.

organiques tels que les polyacrylates comme le Dispex N40@ (vendu par la société Coatex). Many dispersing agents can be used such as inorganic dispersing agents such as sodium hexametaphosphate (sold by the companies BASF and Aldrich Chimies), and / or dispersing agents

organic such as polyacrylates such as Dispex N40 @ (sold by the company Coatex).

 The paper according to the invention can also contain an antiflocculating agent such as cationic polyacrylamids, coloring agents and / or pigments.

 The paper according to the invention may also contain a sizing agent to make the paper hydrophobic, thereby enabling it to resist humidity. Although any sizing agent may be suitable, rosin or a mixture of one or more products chosen from dimeric ketene alkyls and their derivatives, fluorinated phosphates, anhydrides of fatty chain carboxylic acids, polyurethanes and styrene / maleic anhydride copolymers.

 The present invention also relates to a method for preparing a paper as defined above comprising the following steps: a) mixing paper pulp with magnetizable particles and optionally a dispersing agent; b) removing the water from the pulp of the paper; and c) recovering the paper.

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 Such a process for preparing a paper according to the invention can be carried out on the conventional paper making machines usually used.

 The paper pulp according to the invention preferably has a Schoper's degree of between 10 and 30 SR, preferably between 15 and 25 SR.

 The Schöpper degree corresponds to the degree of drainage of the paper fibers. It can be determined according to standard NF Q50 by following, for example, the technique described below which uses a Schöpper-Riegler device measuring the drainage capacity of a fibrous suspension.

 1 liter (1000 cm3) of a paper fiber suspension containing 2 grams of calibrated dry matter is drained all at once through a canvas. The water passing through the canvas falls into a conical container, the lower part of which includes a calibrated orifice.

 At the start of the experiment, the drainage is rapid. The cone fills and overflows through a side opening. This volume of overflow is collected in a side vessel. After a while, all of the suspension drains from the bottom.

If, for example, a volume of 500 cm3 is collected in the lateral vase, the Schöpper-Riegler degree is determined as follows: (1000-500) / 10 = 50, i.e. 50 SR
A low value in Schöpper degree, 20 SR for example, corresponds to a low resistance to flow of the fibrous suspension.

 A high value in Schöpper degree, 80 SR for example, corresponds to a high resistance to the flow of the fibrous suspension.

 The removal of water in step b) can be carried out by drying, gravity and / or mechanical drainage.

 When the removal of the water is carried out by draining, the process for manufacturing paper according to the invention can be carried out using waste from xerographic engines without it being necessary to separate the magnetizable particles and Toner particles. In fact, these latter particles largely flow into the drainage water.

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 In step a), an anti-flocculating agent, a sizing agent, coloring agents and / or pigments, as defined above, can also be added to the paper pulp.

 The present invention also relates to an article comprising at least one paper as defined above.

 The paper of the invention may correspond to the entire article as defined above or only to a part of this article, such as a strip for example, positioned on this article.

 Such an article can for example consist of a bank note, a puzzle or a piece of a puzzle.

EXPERIMENTAL PART Making paper according to the invention
From a fibrous composition formed from a bleached softwood pulp and a bleached eucalyptus pulp in equal mass proportion, two batches are produced:
1) The first corresponds to so-called brown dough, without subsequent mechanical treatment. The Schopper degree is measured at a value of 17 SR.

 2) The second batch of brown pulp, having undergone a mechanical treatment called refining, which cuts, fibrils and hydrates the fibers of the pulp. The Schöpper degree is measured at a value of 28 SR.

 For each of the two batches, a fibrous suspension is produced in water for two concentrations of the dry solid phase in suspension, ie 2 and 4 g / L.

 This suspension is then poured into a column of experience with a circular base.

 Magnetizable particles are then added to the previous suspension of xerographic engine waste of average particle size between 20 and 60 J.! m.

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 The concentration of these magnetizable particles is measured as a mass fraction of magnetizable particles per unit mass of dry fiber. It is between 8 and 30% by weight in the experiments carried out.

 1% by weight of Dispex N40 @ is introduced into the suspension, relative to the total weight of the paper, in order to obtain better homogenization of the suspension.

 After homogenization of the suspension by stirring, and under the effect of the gravity exerted on the suspension column and a vacuum applied through a fabric at the base of the column, the solid elements present in the suspension are sucked up and go separate from the liquid phase.

 They will thus be gradually retained, first on the canvas, then on the fibrous mattress being formed.

 The magnetizable particles are thus trapped mechanically, then chemically, in the fibrous structure.

 When the drainage is completed, the resulting fibrous mat, called a form, contains the fibrous elements and a certain amount of magnetizable particles.

 The tests with a fibrous suspension of concentration 4 g / L, of Schöpper 17 SR degree and a mass concentration of 20% of the magnetizable particles led to a retention of 0.42 g of the magnetizable particles compared to the 0.80 g introduced.

 The tests with a fibrous suspension of concentration 4 g / L, of Schöpper 280SR degree and a mass concentration of 20% of the magnetizable particles led to a retention of 0.25 g of the magnetizable particles compared to the 0.80 g introduced.

 The papers obtained according to the process described above are sensitive to external magnetic fields and can be attracted by a magnet.

Claims (20)

1. A paper sensitive to external magnetic fields, characterized in that it comprises magnetizable particles distributed in the mass of the paper.  2. Paper according to claim 1, characterized in that it contains at least one dispersing agent.  3. Paper according to any one of claims 1 to 2, characterized in that the magnetizable particles are distributed in the mass of the paper homogeneously.  4. Paper according to any one of claims 1 to 3, characterized in that the magnetizable particles have an average size between 20 and 60 lit.  5. Paper according to any one of claims 1 to 4, characterized in that the magnetizable particles are obtained from waste from developers of xerographic engines.  6. Paper according to any one of claims 1 to 5, characterized in that the magnetizable particles consist of a material comprising iron, oxygen, copper and zinc.  7. Paper according to any one of claims 1 to 6, characterized in that the magnetizable particles consist of a material comprising from 60 to 90% of iron, 30 to 40% of oxygen, 10 to 20% of zinc and 0 to 10% copper, in atomic percentage.  8. Paper according to any one of claims 1 to 4, characterized in that the magnetizable particles are microspheres of stainless steel such as stainless steel.  9. Paper according to any one of claims 1 to 8, characterized in that the weight of the magnetizable particles is between 2 and 75% relative to the total weight of the paper. <Desc / Clms Page number 10>  10. Paper according to any one of claims 1 to 9, characterized in that the weight of dispersing agent is between 0.05 and 2% relative to the total weight of the paper.  11. Paper according to any one of claims 1 to 10, characterized in that the dispersing agent is chosen from inorganic dispersing agents such as sodium hexametaphosphate, and / or organic dispersing agents such as polyacrylates such as Dispex Nose 12. Paper according to any one of claims 1 to 11, characterized in that it contains an anti-flocculating agent such as cationic polyacrylamids, coloring agents and / or pigments.  13. Paper according to any one of claims 1 to 12, characterized in that it contains a sizing agent such as rosin or a mixture of one or more products chosen from dimeric ketene alkyls and their derivatives, fluorinated phosphates, anhydrides of fatty chain carboxylic acids, polyurethanes and styrene / maleic anhydride copolymers.  14 A process for preparing a paper according to any one of claims 1 to 13, characterized in that it comprises the following stages: a) mixing paper pulp with magnetizable particles and optionally a dispersing agent; b) removing the water from the pulp of the paper; and c) recovering the paper.  15. The method of claim 14, characterized in that the paper pulp has a Schopper degree between 10 and 30 SR.  16. Method according to any one of claims 14 to 15, characterized in that the magnetizable particles are waste from xerographic engines.  17. Method according to any one of claims 14 to 16, characterized in that in step a) is added to the paper pulp an antiflocculating agent, a sizing agent, coloring agents and / or pigments . <Desc / Clms Page number 11>  18. Method according to any one of claims 14 to 17, characterized in that the water is removed in step b) by drying, gravity and / or mechanical drainage.  19. An article characterized in that it consists, entirely or in part, of a paper according to any one of claims 1 to 13.  20 Article according to claim 19, characterized in that it consists of an article chosen from a bank note, a puzzle and a piece of a puzzle.