DE2025514A1 - Method and arrangement for transporting magnetic powder - Google Patents

Description

Dipl.-Phys. Leo Thul

Patent attorney

Stuttgart

F.P. Mason - F.A.O. Goods - 79-3

Creed 6 Company Limited, Brighton, Sussex, England.

Method and arrangement for transporting

Magnetic powder

The invention relates to a method and an arrangement for transporting magnetic powder over a stationary carrier in FIG magnetic-based printing and / or display devices

The methods that have become known so far for the aforementioned purpose and arrangements for transporting the magnetic powder from the storage container to the point of need, work primarily with rotating Conveyor belts or vibrating devices

The problem to be solved here is the movable transport links to be sealed against the stationary ones in such a way that the magnetic powder cannot get through between them. In solving this problem, however, there are considerable difficulties to be overcome with regard to the fine grain size of the magnetic powder »

The method according to the invention eliminates these difficulties avoided by eliminating the need for a moving transport

20 »May 1970

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F.P. Mason - F.A.O. Goods - 79-3 member is bypassed.

The invention is characterized in that the carrier, which is made of non-magnetic material, moves in the opposite direction Magnetic field moving parallel to the transport direction with relative large scatter area acts periodically on the magnetic powder, the magnetic powder during each phase of influence by the magnetic. field is erected and turned in the direction of transport.

Using this method, it is possible to use mobile means of transport to waive, so that the transport path of the magnetic powder can be hermetically sealed. This is also with Safety the previously existing risk of contamination of the device banned by magnetic powder escaping in an uncontrolled manner,

On the basis of an exemplary embodiment, the invention is connected explained in more detail below with the drawings.

In the drawings show:

La to Ie to explain the method according to the invention the sequence of a transport process in several individual steps.

2 shows a simple one based on the principle of FIGS Embodiment.

3 shows a schematic perspective illustration of a magnetic

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Printing and / or display device in which the method finds application according to the invention.

FIG. H shows a side section of the device from FIG. 3.

f)

In FIGS. 1 a to 1e, which are chronologically successive instantaneous representations, a stationary, non-magnetic carrier 1 is shown, on the surface 2 of which there is a small amount of magnetic powder 3. Below the carrier 1 there is a bar magnet A which is movable in the direction of the arrow A and whose magnetic field 5 penetrates the carrier 2 in the form shown schematically.

With the movement of the magnet 4 in the direction of arrow A parallel to the carrier 1, the magnetic powder 3 located on the surface 2 is finally influenced. The magnetic forces acting on the powder can be broken down into two components, ie into a horizontal component, which acts parallel to the surface 2, and a vertical component, which acts perpendicular to the surface 2. With regard to the method, it is essential that the horizontal component is never large enough to move the magnetic powder heap 3 in the direction of movement of the magnet H, that is, the force of this component must not be greater than the friction between the Powder and the surface of the carrier. This requirement can be met by a magnet whose strength in relation to the distance from the surface 2 has a suitable size, the

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Surface 2 of the carrier 1 may have a certain roughness to a better adhesion of the powder to the surface of the carrier guarantee. ;

In FIG. 1 a, the magnet 4 is still far enough from the powder 3 away, so that there is still no influence from the magnetic field he finally the position shown in Fig. Ib, in which the magnetic powder arranges itself in alignment with the acting magnetic field, i.e. away from the magnet.

The further movement of the magnet leads it according to FIG. With the continuation of the magnet H, the powder accumulation according to FIG. Id ₉ inclines in the opposite direction according to the course of the acting magnetic field. If the magnetic f reaches the position shown in Fig. ₈ Ie it is back far enough from the magnetic powder piles 3 removed it. still noticeably influencing it.

It can be seen from the above that the magnet H is moved from left to right in P> filing direction A, but the piles of powder 3 are displaced in the opposite direction, the displacement being approximately equal to the piling of the powder under the action of the magnetic field. This phenomenon is widely referred to as "turning over ⁸¹¹ the magnetic powder,

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If the above sequence is repeated and the magnet H every time it returns to its starting position (Fig, la) without affecting the magnetic powder during the return movement, a creeping movement takes place Movement of the magnetic powder heap 3 on the surface 2 in the opposite direction to the magnet movement

A simple extension of this principle is shown in the embodiment of FIG. 2, in which the surface 2 with a magnetic powder coating 6 is covered and the magnet 4 extends across the entire width of the Carrier extends.

In this case, the magnet 4 moved in the direction of arrow B causes a feed region 7 extending over the entire width for displacing the support 6, which results in the powder coating has been shifted by a small amount in the opposite direction to the magnet movement.

The surface 2 becomes in constant repetition and in constant Direction influenced by the field of the magnet 4, so the support 6 moves slowly in the opposite direction * In the two In the cases described above, it is of course not necessary for the subsequent scanning to be carried out by one and the same magnet, but rather several magnets can be provided, which come into effect one after the other.

In connection with Fig. 3 and Fig. K , an embodiment of the invention applied to a printing and / or display device according to

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explained in more detail below.

The device is provided with a drum 10 whose axis of rotation 11 in opposite housing walls 16 is mounted »The cylindrical surface 12 of the drum is magnetizable» In a manner known per se, this does not take place during the drum rotation The illustrated, stationarily arranged © recording heads in the to printable and / or visible form.

A collecting and storage container 13 is arranged below the drum 10, into which magnetic powder 14 can be refilled via a filling chute 15. The container 13 is sealed laterally by the housing walls 16 "A" s non-magnetic material, for example aluminum, existing pipe 17 extends horizontally along the container 13 and closes at its ends tightly with the walls 16, so that the in the container Magnetic powder cannot get inside the tube. A horizontally lying wiper 18 made of non-magnetic material extends tangentially from the upper edge of the tube 17 to below the drum 10, closely adjacent to the surface 12,

A magnetic rotor 19 is rotatably mounted about axis 20 within d © @ Rotees 17 _s Des? Rotor 19 consists of glsisr Vielsahl parallel disposed bar magnet © 21. _ß which according to FIG ₀ 3 aligned in d @ r Aefog © 20 mg @ QT dm @ t sisid and together form a flat, s? @ © ht @ ekig <sa magnet bildes ^ Όρ.β aiah% wi ~ see Magaetf © ld ^ e ^ ilfcft L ·,:? <

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F.P. Mason - F.A.O. Goods - 79-3 * u ^ o.-T

Angle to the pipe's longitudinal axis (Fig. «Ο · In some cases it can be advantageous be to provide the bar magnets with pole ends made of soft iron »to get a better flux distribution *

The arrangement of the exemplary embodiment in FIGS. 3 and 3 is corresponding the principle explained to Fig. 1 and Fig. 2 in their effect so that by the rotation of the rotor 19 in the direction of the arrow B (FIG. U) a powder coating 22 on the surface of the tube 17 forms, which, fed from the magnetic powder supply 14, in the direction of the arrow C on the outer surface of the tube 17 by repeating "Turning" crawls forward and ultimately over the scraper 18 is fed to the drum surface 12 »The powder particles remain on the pipe surface due to the on the neighboring particles exerted attraction stick · However, in order to avoid the "flip-over process" to support, it may be necessary to modify the surface of the To artificially roughen the pipe. It has been used for this purpose as a shown advantageous, the pipe surface in the longitudinal direction with To work on medium-grain sandpaper.

Exactly as the support 22 creeps around the pipe outer surface, distributed they also automatically run along the entire length of the pipe, like that that the container 13 can only be refilled at one point needs. This takes place in the aforementioned manner via the feed chute 15.

The drum 10 rotates in Pfexlrichtung D. Your surface 12 arrives while in contact with the magnetic powder coating located on the stripper 18. This will magnetize them beforehand

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Regions of the surface 12 contacted with the magnetic powder. This forms due to the adherence of powder particles
record to be printed or made visible in the form of a
Magnetpulverbildesi In the embodiment described above, the purpose of the scraper 18 is that the drum 10 can be moved laterally to the tube 17 so that the drum surface 12 is not dusted directly by the rotor 19. The remaining magnetic powder, which does not adhere to the magnetized drum surface 12, falls back into the storage container 13 at the end of the scraper 18.

5 claims

3 sheets of drawings, 4 figs,

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Claims (1)

- ⁹ - 20255U F.P. Mason - F.A.O. Goods - 79-3 Claims 1) A method for transporting magnetic powder over a stationary carrier in magnetic-based printing and / or display devices " characterized " that by means of the carrier made of non-magnetic material, a magnetic field moving in the opposite direction to the transport direction with a relatively large scatter range periodically impacts the Magnetic powder is acted upon, the magnetic powder being erected during each phase of influence by the magnetic field and being turned over in the direction of transport. 2) Arrangement for performing the method according to claim 1, characterized in that the carrier is a convex surface in the transport direction. which rises from the magnetic powder supply (m) to just below the surface to be dusted and that behind this surface a magnetic rotor (19) is rotatably mounted, the magnetization of which is directed transversely to the axis of rotation (20). 3) Arrangement according to claim 2, characterized in that «the carrier is designed as a tube (17)» that a scraper (18) made of non-magnetic material rests tangentially on the upper side of the tube (17) and that the rotor (19) is an off a lot. composed of bar magnets (21), flat long- - 10 00 9850 / U 77 20255H FiP. Mason - F.A.O. Goods - 79-3 stretched magnet is " 4) Arrangement according to claim 2 and 3, characterized «that the tube (17) extends inside and along a collecting and storage container (13) for the magnetic powder. 5) arrangement according to claim 2, characterized in that the _t on pollinating the surface is a drum (10) and in that this drum is offset (10) relative to the tube (17) with rotor (19) horizontal. May 20, 1970
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