FR2522838A1 - Line of force straightening device for magnetic printer - reveals latent magnetic images by particles on magnetic support - Google Patents

Abstract

The device has a transversally magnetised magnetic registration support (2) carrying magnetic damains (4) representing latent magnetic images. The images are revealed by means of a device (10) for application of magnetically attractive particles which form deposits (11) on the registration support. A device (37) for straightening the lines of force (20) associated with the magnetic domains during the application of the particles improves the deposits. It consists of a piece of soft ferromagnetic material having one face (38) opposite the surface (5) of the registration support and opposite the zone (41) where the particles are applied. The line of force straightening piece also acts, therefore, as a deflector for the particles. The face (38) has a width (D2) two and a half to five times that of the magnetic domains (D1). The face is situated at a distance (D3) from the surface of the registration support of the same order of size as the domains.

Description

 The present invention relates to a device with means for straightening lines of force, for revealing magnetic latent images carried by a magnetic support with transverse magnetization. It applies in particular to the production of magnetic printing machines known as non-impact or transfer without striking, known machines in which the printing of the characters is carried out without for this calling upon the impact of types of relief printing on a sheet of receiving paper.

 An exemplary embodiment of such a non-magnetic impact printing machine is shown schematically in FIG. 1. It comprises, in a manner known in the prior art, a magnetic recording medium constituted, in the 'example considered, by a magnetic drum 2 rotated by an electric motor (not shown). The recording of information on this drum is carried out by a magnetic recording member 3. In the example considered, this member 3 is formed by an assembly comprising several magnetic recording heads which, placed one side of the others, are aligned in parallel with the axis of rotation A1 of the drum 2. Each of these heads generates, when it is excited repeatedly by an electric current, a variable magnetic field, which has the effect of creating magnetized domains 4, also called magnetic hands or magnetic points, on the surface 5 of the drum which passes in front of the recording device soak 3, the instants of excitation of these heads being established in a known manner, so as to obtain on this surface of the drum of the magnetized zones which are sets of magnetic domains 4, sets also called magnetic latent images and whose shape corresponds to that of the characters to be printed. r then pass in front of a device 6 for revealing latent images which is arranged below the drum 2 and which comprises means for applying, to the surface 5 of the drum, particles of a powdery pigment 7 contained in a reservoir 8 In the example described, this pigment consists of magnetic particles coated with a resin which, when heated, is capable of melting and fixing on the paper on which it has been deposited.

 As can be seen in FIG. 1, the application means comprise, in a manner known in the prior art, on the one hand a transport element 9 consisting for example of a rotary magnetic cylinder which takes up pigment particles hole in the tank 8 to bring them near the surface of the drum 2, on the other hand, a fixed deflector 10 which is interposed between the transport element 9 and the drum 2 to collect the transported particles by this element 9 and apply them to the surface of the drum 2.

 the pigment adheres mainly to the magnetized areas 4, thus forming deposits 11 of particles & the surface of the drum 2. Touch-up means 12 consisting for example of a rotating magnetic cylinder placed in the vicinity of the drum 2 are then provided to remove the particles having adhered elsewhere than on the magnetized domains 4 as well as the excess particles on said domains. A small deflector 13 is provided in the vicinity of the retouching means 12 for causing the particles captured by said means to fall back into the reservoir 8. After which, the particles are transferred to a support sheet such as a sheet of paper 14 applied against the drum thanks to a transfer roller 15.

Finally, the particles which remain on the drum are removed in a cleaning station 16 then the magnetic dots are erased by an erasing module 17, after which a new printing cycle can take place.

 In Figure 3, there is shown schematically a part of the magnetic drum 2 seen in section, on a large scale, so that the magnetic point 4, also shown, has in this figure a sufficiently large size. As such a magnetic point can have a real size of the order of 100 to 200 μm, that is to say present for example a square section of the order of 100 to 200 ssm sideways, it is understood that, on the Figure 3, the surface 5 of the drum 2 appears flat while it is actually curved.

 This drum consists, in a manner known in the prior art, of a core 18 serving as a magnetic shunt and made of a soft ferromagnetic material, that is to say & high magnetic permeability, core on which is deposited a layer 19 of a ferromagnetic material with low magnetic permeability or magnetically hard material. The magnetic points 4 are created in the layer 19. This layer 19 is moreover provided to be with transverse magnetization.

We then say that the recording medium is transversely magnetized. By 1 is meant a support on which the magnetic points formed have magnetization axes perpendicular to said support. The lines of force 20 associated with the points 4 thus normally intersect the surface of these points, as can be seen in FIGS. 3 & 5 and 7. In these figures, we have assumed the layer 19 such that the magnetic points 4 all have magnetizations of the same direction, that is to say all have the same magnetic face, in this case a south face in FIGS. 3 to 5 and 7, on the surface 5 of the drum 2. Another layer 21, made of a non-magnetic material, is generally interposed between the layer 19 and the core 18, for reasons of behavior of the material constituting the layer 19 on the material constituting the core 18.

 The magnetic recording medium can also be constituted, as seen in FIG. 2, by an endless magnetic strip 22 with transverse magnetization, homologous with the layer 19 of FIG. 3 and mounted stretched on rollers 23, 24 , 25, 26, this strip being held pressed against a magnetic shunt 27 consisting of a bar with high magnetic permeability. The magnetic non-impact printer shown diagrammatically in FIG. 2 naturally includes the various components mentioned in the description of FIG. 1, such as the magnetic recording member 3, the device 6 for revealing latent images, the retouching means 12, ... The magnetic recording member 3 and the bar constituting the magnetic shunt 27 are arranged opposite one another, the magnetic strip 22 circulating between them and the magnetizable surface 5a of the strip 22 being turned towards the member 3. The scrolling movement of this strip is provided by an electric motor, not shown, which drives one of the rollers in rotation, the other rollers being free to rotate. A support block B can be placed on the other side of the strip 22 relative to the deflector 10, a block which serves to promote the application of the particles to the strip, while maintaining the latter in position.

 Returning to FIG. 3, it can be seen that the outermost lines of force 28, lines intersecting the magnetic point 4 in the vicinity of its periphery, have an almost circular appearance and also intersect the layer 19 in non-magnetized zones 29 of this layer. These lines of force 28 therefore form arches on the surface 5 of the drum, arches of which one end is at the magnetic point 4 and the other end outside this point. When the pulverulent pigment is applied to the surface 5 of the drum 2 (moreover constituting the external surface of the layer 19), certain magnetic particles 30 which constitute this pigment will of course adhere to point 4 and other particles 31 of said pigment will be placed outside point 4, along the lines of force 28 forming arches and thus forming songs 32 of particles.

 When a magnetic point 4 passes in front of the retouching means 12 (FIG. 1), the chains 32 (FIG. 3) are broken and lose most of their particles, except the particles 33 (FIG. 4) located behind point 4, on the surface 5 of the drum 2.

(In FIG. 4, the direction of movement of this drum is indicated by an arrow F1: it goes from the strike to the right, the retouching means not shown then being located on the right of FIG. 4). This results in a streak for the deposits of particles obtained using the said dots and therefore also in an unpleasant sight for the characters formed from such deposits, once these characters have been printed, which is a drawback. This trat nde phenomenon is all the more marked the larger the size of the magnetic points.

 Furthermore, Figures 3 and 4 highlight the phenomenon called "edge effect", according to which the gradient of the magnetic field created by a magnetic point 4 is more intense on the edges of said point than in its center. This edge effect is all the more marked the larger the point. The particles of pigment have for example a size of the order of 25 m, size significantly smaller than that of a magnetic point which can be of the order of 100 or 200 μm, and will therefore preferably adhere to the edges magnetic points since the force of attraction, proportional to the modulus of said gradient, is more intense there. This effect is even more marked in the case where the particles have high magnetic permeability. This results in an unpleasant appearance of the characters formed from the deposits of particles obtained using the said dots, once these characters have been printed, which constitutes another disadvantage.

 The present invention relates to a device for revealing magnetic latent images which does not have these drawbacks, in particular in that it avoids the formation of said streaks and in that it reduces said edge effect.

 Specifically, the subject of the present invention is a device for revealing magnetic latent images formed by magnetic domains carried by a magnetic recording medium with transverse magnetization, a device of the kind which gui Cour take means for applying particles attractable by a magnet, on the recording medium, so as to obtain deposits of particles on said medium, characterized in that it further comprises means for straightening the lines of force associated with said magnetic domains during the application of the particles on said domains, so as to improve the deposits of particles produced on the recording medium.

 According to a particular characteristic of the device which is the subject of the invention, said re-erecting means consist of at least one piece made of a soft ferromagnetic material and having a face arranged facing the surface of the recording medium and facing the area where the particles are applied.

 According to another particular characteristic, said application means comprising a transport element designed to supply particles to the surface of said support by means of a deflector interposed between this support and the transport element, said part is also provided to constitute said deflector.

 According to another particular characteristic, said face of the part has a width of the order of two and a half to five times the size of the magnetic domains. Then, preferably, said face of the part is also located at a distance from the surface of the recording medium of the order of magnitude of the size of said areas.

The invention will be better understood on reading the following description of an exemplary embodiment given by way of non-limiting example, with reference to the appended drawings in which:
FIGS. 1 and 2 are schematic views of particular embodiments of magnetic non-impact printers known in the state of the art, and have already been described,
FIG. 3 is a diagrammatic section on a large scale of a part of a magnetic drum, showing a deposit of magnetic particles on the surface of said drum, and has already been described,
FIG. 4 is a schematic view of said deposit after retouching and has already been described,
FIG. 5 is a schematic view of the deposit of FIG. 3 carried out in the presence of a surface made of a soft ferromagnetic material,
FIG. 6 is a schematic view of a particular embodiment of the device which is the subject of the invention, and
- Figure 7 is a detail view of Figure 6.

 In FIG. 5, a part of the drum 2 provided with the layer 19 made of a hard ferromagnetic material is shown schematically and still on a large scale, this layer comprising magnetic points 4, one of which is shown in FIG. 5. A piece 34 made of a soft ferromagnetic material is disposed near the layer 19 and has a surface 35 facing the layer 19 and above the magnetic point 4. The surface 35 of the piece 34 is for example flat or still has a rounded shape of curvature close to that of the drum. The presence of this surface 35 has the effect of straightening the lines of force 20 and in particular the lines of force 28, in the form of arches, of FIG. 3, except may be the most peripheral lines of force 36, to which correspond arches whose one end is very close to the other and which do not contribute to the phenomenon of tratnea. Aside from these lines of force 36, all the other lines of force 20 connect the magnetic point 4 to the surface 35 of the part 34. The straightening of the lines of force is explained by considering the magnetic image of the magnetic point 4 by surface area 35.

 It is therefore understood that, when magnetic particles are applied to the surface 5 of the drum 2, these particles will deposit on the surface of the magnetic point 4 and also collect from the latter, following the lines of force. 20.

 However, given that the arches which were responsible for the drag phenomenon have disappeared, we no longer observe the chains 32 of particles of FIG. 3 and we take it that this drag phenomenon disappears at the impression of the characters.

 Furthermore, the presence of the surface 35 of the part 34 facing the magnetic point 4, overlaps a reduction in the gradient of the magnetic field created by the point 4, i the periphery of said point. More precisely, the variations of the gradient of the magnetic field, of the center dupiFtvea assboMb, are made less important.

On this point, the deposit 11 of particles is then substantially uniform and the hollow in the center of the point, visible in FIG. 3, is no longer observed.

 In Figure 6, there is shown schematically a particular embodiment of the device for revealing latent images object of the invention.

I1 comprises a fixed deflector 10, placed in the vicinity of the surface 5 of the drum 2 and below said drum which is rotated by a motor not shown, in the direction indicated by the arrow F2. A transport element 9, constituted for example by a rotary magnetic cylinder of axis A2 parallel to the axis
Al of the drum 2 (FIG. 1) is provided for supplying the drum 2 with particles, via the deflector 10. This deflector 10 is formed of a part 37 made of a soft ferromagnetic material. This part 37 has for example a flat face 39 inclined with respect to the surface 5 of the drum 2 and limited by a first and a second edge 42 and 43 parallel to the axes A1 and A2. The first edge 42 is in the vicinity of the element 9. The second edge 43 is in the vicinity of the surface 5. The flat face 39 forms with the normal 40 on the surface of the drum, considered at a point of intersection of this surface with the plane of the planar face 39, an angle a whose value lys is between 0 and 450, and for example of the order of 20. Furthermore, the part 37 has a face 38, planar for example, perpendicular to the normal 40 and limited by the second edge 43 and by another edge 44. The part 37 is moreover completed by two other faces, one of which 38a is horizontal and has the edge 42 in common with the flat face 39 and the the other 39a is vertical and has the edge 44 in common with the face 38. These two other faces 38a and 39a intersect for example at right angles along a common edge 45.

 The direction of rotation of the transport element 9. represented by an arrow F3, is intended to animate the pigment 7 in an upward movement leading this pigment towards the flat face 39 of the deflector 10. The direction of rotation of the drum 2 is intended to then drive the pigment 7 towards the second edge 43, after which this pigment passes into the area 41 shown on a large scale in FIG. 7 and between the face 38 and the surface 5 of the drum 2. In this area, the pigment is applied to said surface 5. Part of the pigment is fixed on the magnetic points 4 (FIG. 7), present opposite the face 38, to give deposits ll of particles and the rest of the pigment, which has not not fixed, falls back into the unrepresented tank containing the pigment.

 When a magnetic point passes opposite the face 38, its lines of force 20 are straightened Coxr explained to me in connection with FIG. 5, and, simultaneously, particles of pigment adhere to this point. When the point thus provided with a deposit 11 of particles turns blank on the face 38, due to the movement of the drum 2, some of the lines of force associated with said point form arches 28 but there is then no formation of particle channels.

 By way of non-limiting indication, the magnetic points 4 have a size of the order of 100 s (respectively 200 m), that is to say that they appear for example as parallelepipeds whose base is a square side D1 of the order of 100 μm (respectively 200 μm>, the width 2 of the face 38, counted perpendicular to the axis Al, is of the order of 500 m (respectively 1000 m) and this face 38 is at a distance D3 of the order of 100 ssm (respectively 200 m) from the surface 5 of the drum 2. Finally, the length of the part 37, and therefore the length of the face 38, counted parallel to the axis Al, are for example of the order of the length of the drum 2.

 It will be noted that in FIGS. 3 to 5, the layer 19 is shown facing upwards of these figures, for a better understanding of the invention, while this layer 19 is represented with its actual orientation in FIGS. 6 and 7.

 Of course, as already indicated, the invention applies to the case where the magnetic recording medium is constituted by an endless strip 22 shown in phantom in Figure 6. The face 38 is then arranged in parallel to the magnetizable surface 5a of this strip 22, surface 5a homologous to the surface 5 of the drum 2, and the length of the part 37, counted parallel to the axes of rotation of the rollers of FIG. 2, is then for example of the order of the width of the strip 22.

 Of course, also, the invention applies to a magnetic recording medium with transverse magnetization for which the axes of magnetization of the magnetic points are all in the same direction or to a magnetic recording medium with transverse magnetization for which the magnetization axes of the magnetic points are of alternating directions.

 It may be added that, in the case of a pigment formed from particles of high magnetic permeability, the invention also has the advantage of increasing the adhesion strength of said pigment on the magnetic points. Indeed, the magnetic field in the vicinity of these points is increased by the addition of a soft ferromagnetic surface and the adhesion force is proportional to the product of this field by its gradient.

Claims (5)

 1. Device for revealing magnetic latent images formed by magnetic domains (4) carried by a magnetic recording medium (2, 22) with transverse magnetization, device of the type which includes means (9, 10) for application of particles (30) attractable by a magnet, on the recording medium (2, 22), so as to obtain deposits (11) of particles on said support (2, 22), characterized in that it comprises further means (37) for straightening the lines of force (20) associated with said magnetic domains (4) during the application of the particles to said domains, so as to improve the deposits (11) of particles produced on the support ( 2, 22) recording.  2. Device according to claim 1, characterized in that said straightening means track in at least one part (37) made of a soft ferromagnetic material and having a face (38) disposed opposite the surface (5, 5a ) of the recording medium (2, 22) and opposite the zone (41) where the application of the particles is carried out.  3. Device according to claim 2, characterized in that, said application means (9, 10) comprising a transport element (9) designed to supply particles to the surface (5, Sa) of said support (2, 22) by means of a deflector (10) interposed between this support (2, 22) and the element (9) of transport, said part (37) is further provided to constitute said deflector.  4. Device according to any one of claims 2- and 3, characterized in that said face (38) of the part (37) has a width (D2) of the order of two and a half to five times the size (D1) (4) magnetic domains.  5. Device according to claim 4, characterized in that said face (38) of the part (37) is further located a distance (D3) from the surface (5, Sa) of the recording medium (2, 22) of the order of magnitude of the size of said domains (4).