DE2428864C3 - Carrier for cutting knife and converter in a foil storage - Google Patents

Description

The invention relates to a carrier device for at least one cutting knife and at least one opposite this movable transducer in a data memory with at least one rotating stack flexible recording medium, the axial distance of which is less than the corresponding dimension for data recording or -scanning serving transducer, and which can be spread apart by means of the separating knife are, so that the transducer can be brought into working position with respect to a recording medium can.

Such data memories with rotating stacks of flexible magnetic foils, so-called foil memories are described, for example, in U.S. Patents 3509553, 3618055 and 3703713. at

In this way the selected imaging plate is placed in the stack through a slot or guide channel a rigidly attached control mechanism isolated and guided. To give access to the selected slide allow, all the rest are pushed away to the side. The drive mechanism also includes one Transducer, which is arranged on the guide channel, the movement of the mechanism in addition to it is designed to set the converter to a specific track of the selected imaging plate. In a Arrangement, externally compressed air is introduced into the duct through the transducer head and thus a hydrostatic one Air bearings formed. Among the factors affecting the bit density and the operation of such storage devices affect the braking effect of the device working as a guide channel and their wear compared to the magnetic foils and the aerodynamic stability of the entire stack of foils regarding the control mechanism. the

äpreizvorgang venirsadit irregular air flows, which the driven slide in the guide causes ium flutter. Access is, if not prevented, delayed. In addition, the film can be subjected to severe stress due to wear and tear. Keeping a minimum distance between the magnetic head and the film is also restricted by the design of the guide channel. Lynott et al. (IBM Technical Disclosure Bulletin, Vol. 12, No. 1, June 1969, page 81) propose to separately attach spreading and transducer devices for similar film arrangements Foil stack are axially deflected, while the other on the exposed area of a magnetic foil in the separating space is intended to activate a ¹ S transducer head. This proposal requires foils of considerable strength and thickness, because the spreading device only acts on the edge zone of the first of the foils to be deflected If there are fluttering phenomena in the stack, this film * ° is excessively stressed and can escape guidance by shearing. Necessary precautions for stabilizing the non-deflected films are not shown here, so that an unhindered positioning of a transducer head in relation to the films is not guaranteed Also, there are no precautions to maintain a consistent minimal Ensuring the distance between the magnetic head and the storage film, which would be a prerequisite for high storage density and low wear.

U.S. Patent 3,130,393 describes an array of stacked storage disks that can be used without Deformation are shifted axially. The pairs are similar to a flask from an airtight Enclosed jacket and are pneumatically forced apart axially by a high pressure air jet. This type of construction is rather cumbersome, as the volume, mass and separation force are several orders of magnitude higher than other known systems. A second piston-like device regulates 4 » the position of the transducer assembly, obviously to compensate for irregularities on the plate surface. This system, however, appears to be less adaptable and not as effective as elsewhere to be described facilities. The transducer head is likely to hit the plate too hard prone to further damage to the records. The rigid, axial displacement of a selected Part of the stack of plates forms a significant difference to the axial spreading of flexible magnetic 5 < > foils on part of the rotation path.

Based on this prior art, the invention has set itself the task of possible contacts between the transducer and the recording medium surface to be scanned or written to to be avoided altogether. This is intended to damage or even destroy the converter be prevented. True, such damage or destruction would be due to the use of a new one The converter can generally be repaired without loss of information, but this replacement is a time consuming one Process that can only be carried out by qualified specialists.

Damage or destruction of the magnetic, for example, would have far worse consequences Storage layer on the recording medium. This is because it contains - as with every reading process - items to be scanned Information, as the storage layer is destroyed, so too will the information it contains irretrievably destroyed.

If one also takes into account the very high recording densities per surface area of the storage medium, which can be achieved by modern recording rivets, it will be apparent that Any damage to the storage layer must be avoided as far as possible in order to ensure reliable recovery to make the stored information possible. From this point of view is also the Training of the recording media for introduction the transducer separating mechanism - here called spreading device - special attention to give. The separating knife of this spreading device can damage the storage layer the recording medium lead, which must be avoided in any case. This task too solves the invention.

Another problem that has not been given any attention in the present prior art results from the fact that the flexible film stack is a vibratory system acts. The disturbance of the steady state of such a system - for example by Introduction of a cutting knife - allows vibrations to occur, which also lead to damage Lead converter, cutting knife and above all storage medium as a result of mutual hard contact be able. The invention has also set itself the task of avoiding these difficulties.

The solution to these tasks is to train one Carrier device of the type mentioned in the manner specified in claim 1. By this arrangement, the above-mentioned disadvantages of the known devices, in particular the contact between cutting knife, transducer and recording medium is largely avoided. Besides that a damping of the vibration of the film stack generated when the cutting knife is retracted achieved.

According to a further development of the invention, the cutting knife and sliding body have separate actuating devices on. This makes it possible to start with the relatively insensitive and also large-area Introduce cutting knife into the plate stack and only after reaching a steady state the entire arrangement to bring the sensitive transducer into working position.

Another appropriate embodiment is that the sliding body in the axial direction of the stack of foils resiliently, in particular by means of a double spring composed of two parallel leaf springs is. This resilient arrangement, which is still easy to adjust for the force exerted on the sliding body is the formation of a hydrodynamic gas bearing guaranteed between sliding body and recording medium.

The stabilization of the stack of films can be further improved by the fact that for damping the at Introducing the cutting knife resulting vibrations and on the other hand one opposite the Stacks of fixed, channels provided with holding plate are provided. Further refinements of the dei Invention emerge from the claims.

For a better understanding of all the details of the invention below, reference is made to the detailed description referenced. Show it

1 to 3 plan, elevation and side elevation of the cylinder 34, the piston rod 32 is displaced

inventive device, to the outside and brings the cutting knife 28 with the

Fig. 4 stack of foils and stabilizing elements, rotating stack of foils at the edge of the selected one

Fig. 5 graduated diameters to facilitate imaging plate in contact. This will take care of this

the control of individual imaging plates, 5 digit the rotation path of the stack in two segments

6 shows a cutting knife, divided, one of which is deformed and the other of which is deformed

Fig. 7 an arrangement for fastening and BeIa- not. The segments run apart in front of the knife

stung of the transducer head, which and behind this together again. they form

8 shows a comparison of the shape of the opening around the cutting knife, which

Converter to the elastically deformed surface that allows access with a converter,

controlled imaging plate, which lets the air out of the cylinder 34

9 to 13 representations of the film stack for the piston rod 32 under the pressure of a not shown

Explanation of the stabilization processes, return the spring to the rest position.

14 to 22 a cutting knife in different ways

Positions, 15 stacks withdrawn. In this position the

23 shows a double access device, spindle 40 and slide 18 parallel to the axial direction

24 move several film stacks on a common shaft 11. This movement is going through

men wave, the indicated drive means and caused

25 shows another arrangement with a resilient one used to find a further selected one

converter attached to the cutting knife. 20 Image plate in which the spreading process is repeated

According to FIGS. 1 to 8, the invention is to be fetched. The special shape and the

Device made from a layered stack of foils 2, the sequence of movements of the cutting knife together

Stabilization devices 4a, 4b and 4c and from men with the damping to be described through

the access device 6 together. The foil stabilization elements that the stack despite lower

pel 2 consists of several hundred extremely thin masses very quickly, i.e. within 0.2 s, an aero-

(Thickness about 0.043 mm) assumes vertically arranged, dynamically stable rotational form after

Magnetic imaging plates 8, which are circular and flexible when the first contact with the knife took place

are. They are fastened by means of the flanges 10a.

and 10b on the horizontal shaft 11. The drive The converter device 22 (FIGS. 7, 8) comprises a shaft 11 which takes over the motor 12 (FIG. 4). The Fon magnetic head 44, which is elastically deformable in a ceramic holding line which is enclosed outside the circumference of the flanges 10a and 46, the rounded edges with ver- 10b , have different radii of curvature. The magnetic knife of about 30.5 cm. Every second film is, however, head 44 with its holder 46 together, reduced to a diameter of about 29.7 cm, form a sliding body 48 with low mass and adapted (FIG. 5), thus by a special device (in a form adapted to the Plates of the stack 2. It is not shown in the drawing) any foil can be controlled on the two parallel, self-supporting leaf springs. The flexible foils are attached 50. An angle 52 connects this double fiber polyester sheet with magnetizable iron oxide 50 with a carrier plate 54 as cut out layer below. As can be seen from the thickness of the polyester film, the guide surface of the projection 54a is about 0.038 mm, that of the oxide layer about 40 of the plate 54, that the sliding body 48 in the working position 0.005 mm. The rotational speed of the shaft 11 is constantly pivoted with respect to the non-deformed parts at 1800 rev / mm, and the direction of rotation is when it is indicated by arrow 14 in FIG. 3 in the direction created by the cutting knife. Gap is pushed into it

The access device 6 (Fig. 1 to 3 and Fig. 6 The plate 54 runs on the thread of the spindle

to 8) consists of slide 18, spreading device 45 56, which is driven by stepper motor 58 The BoI-

20 and a not shown Foüen control _zen 60 and 62 (Fig. 1,2), which sit on the plate'54,

together. The latter is not part of the scope of the invention; the guide rollers 60a and 62a run

object, and the use of a control along the fixed rod 64 and prevent

££ 20 includes those on frame ₅ o u2 SnESS

25 bent rod, 24 being the ** men 25 on 58 versÄfeS ^ i ^ RSSS the carriage 18 is built up A carrier 26 let from angle 52, plate 54, double spring 50 and sliding

rigidly attached to the carrier 26 isTüi cutting knife 28 ₅₅ SSSSta

(Fig.6) weistmehrereKana 28e _{e a} u £, diemVerbm- IZ through the

dung with the pipelineae air with little over-wind proximityheiA f ^ J ££? £ ^? t

pressure in the mid-point created by the spreading 5 Ä Tlf ^ ^lg - ^?) ^ ST? *?

lead space. The resulting stabilization dfe fS toP'It ^un £ «stationary was wu" d through

of the film stack will be explained later. The carriage 60 fm SSmSUT ⁸ ^ ^ ⁸ "* ^d ^? ° ^ ⁿ

18 can be parallel ™ eh »SS?, F ™ ** I» ^

move to the axis of the stack, where the corresponding? _e "the PJt S ^ T? 2? ^aUS ΐ ™ ^Ra T ^de i

the drive elements S.td are provided. The 5SSbS- ^ S * ⁰ «^ d plate 54 are

Carrier 26 is pneumatic by means of a dryer 34

automatically over the piston rod 32 ^ m stack 2 6 ₅

orfromthis way off-this shift

takes place in an inclined direction to spindle 40. Through

diZ? fh _k l _ft 4diffi

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ter, and the angle lever 68 is pivoted by the coil spring 686 in the counterclockwise direction. The roller 68d moves away from the double spring 50, which is now pressed against the non-deformed storage film (FIG. 7: upwards) through the angle 52. After being released by the roller 68a ¹ , the sliding body 48 swivels from its previous spaced position onto the undeformed image plates.

If the double spring 50 is correctly pretensioned, the sliding body 48 will slide tightly over the surface of the non-deformed film (FIGS. 7, 8). Of interest are the indentation that is adapted to the head profile and created in the rotational surface of the storage disk, the small and constant distance between the sliding body 48 and the film surface and the pretensioning required by the double spring 50 for this purpose.

During operation, the devices 20 and 22, when they are located outside the rotating imaging plates, are moved in the axial direction by the carriage 18. As soon as the tip of the cutting knife 28 is aligned with the activated film, the rotating films are forced apart by the spreading device 20. The knife 28 is pushed deep into the rotation space of the plates until it is aligned with the tendon 69 (FIG. 3). It slides sideways, in the representations of FIG. 2, dog 15 to the right. While the separation space between the deflected and the undeformed foils is gradually widened by the lateral displacement of the knife, the constantly changing curvature of the knife profile opposite the deflected foils enables a stable aerodynamic air film to develop between it and the foils. Thanks to the action of stabilizing elements, which will be mentioned later, the divided rotational structure stabilizes quickly, with the deflected foils sliding smoothly past the cutting knife.

After this stabilization, the converter device 22 is actuated in that the sliding body 48 is introduced radially into the space that is created. The initially existing distance to the non-deformed film is reduced after the angle lever 68 has been pivoted, triggered by the guide surface 54a. The magnetic head is now on the edge or on a track of the activated imaging plate. The pretensioning of the double spring 50, described later, causes the sliding body to produce a slight indentation in the film, a thin film of air of uniform thickness being formed between the sliding body and the surface of the film. With a constant distance from the surface, the sliding body now moves in the radial direction from the edge of the film to the desired track. The drive for this movement is provided by motor 58.

The stabilization of the rotating stack of foils after spreading apart requires measures to dampen those parts that contribute to vibrations and other unstable movements. In FIGS. 4 and 9, a number of flexible disks Ac are shown which, following the imaging plates, act as a progressive spring and dampen the movements of the stack segment deflected to the right (FIGS. 13 to 15). Quantity, dimensions and material of the flexible disks Ac (Fig. 4 and 9, viewed from right to left) are, for example, arranged according to diameter as follows:

Through!

1 piece 3.2 mm thick, aluminum 95 mm

2 pieces 0.19 mm thick. Polyester 98 mm
2 pieces 0.19mm thick, polyester 105 mrr.
1 piece 0.19 mm thick, polyester 108 mm
1 piece 0.19mm thick. Polyester 114 mm
1 piece 0.19 mm thick, polyester 117 mm
1 piece 0.19mm thick. Polyester 121mm
1 piece 0.19mm thick, polyester 130mm
1 piece 0.19mm thick, polyester 151mm
1 piece 0.19mm thick, polyester 298mm

A cladding sheet 4fo in FIGS. 3 and 4 partially envelops the rotary cylinder of the stack of foils over an angle of 90 ° to 105 °. Serving rich! with the edge furthest from the cutting knife up to the extension of the tendon 69 and is approximately aligned with the top edge of the fully immersed knife. The axial length of the cladding sheet covers both the deformed and the undeformed image plates and thus catches all of the air escaping from the separating space. The jacket plate regulates this air flow and thus limits the tendency of the deflected stack segment to oscillate with respect to the separating knife 28. The fixed holding plate Aa in FIG. 4 in turn stabilizes the movements of the stack. Trapped air can escape through grooves and bores from the space between the holding plate and the closest storage film (FIGS. 10 and 11), with damping being achieved.

The air supplied under low pressure through openings 28t in the cutting knife (FIGS. 6, 18 and 19; serves to change the air flow in the space enclosed by the spread film segments, whereby the observed tendency of the undeformed films to oscillate is dampened.

During the advance of the knife 28 to the greatest depth of penetration on the tendon 69 (Fig. 3, 12), the path of rotation of the deflected film segment is deformed to slide continuously and positively around the knife profile (Fig. 13). The movement of the deformed and undeformed segments caused by the spreading process calms down quickly. The axial position and shape of the separating space are then sufficiently precisely defined in order to be able to introduce the converter device without being impaired by the rotating foils.

According to FIG. 6, the profile of the cutting knife changes steadily from the tip 28b to the end 28c, and so does the curvature of the knife surface. This makes the knife similar to an airplane wing in that it gradually deflects and at the same time slidably supports the split stack. The air outlets 28a are mounted at an angle and deliver an air jet at a critical angle of 7 ° to 11 ° to the vertical, ie the closest undeformed imaging plate. The carrier 26, to which the cutting knife is attached, moves at an angle of approximately 4 ° to 11 ° to the plane of rotation of the next unformed imaging plate.

It has been found that the said range of the circumferential angle and the knife profile for the Rapid attenuation during the separation process are critical values if the selected imaging plates are subject to minimal wear and tear target. In the present embodiment according to FIGS. 20 to 22 with alternating diameters, there are the edges are offset from access. The knife lenki without exception the imaging plate with the larger one

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Diameter from, so that the transducer is safely brought up to the film with the smaller diameter can be.

Experience has shown that the pressure exerted by the double spring 50 on the closest, undeformed film must be precisely measured so that a “dimensionally correct depression is created in the image film that lies closely against the sliding body 48. In the event of success, this results in high storage density and low interference signals for operation without wearing out the storage area. The compressive force acting on the double spring 50 and the sliding body 48 is dependent on the axial position of the angle 52 with respect to the plane of rotation of the undeformed film at the separation point. This position can preferably be adjusted in that the axial position of the spreading device 20 relative to the converter device 22 is set by hand on the slide 18. This can be done in such a way that the displacement of the spreading device 20 with respect to the carriage 18 is provided parallel to the axis of rotation of the stack of foils, for example by attaching the frame 25 to the carriage 18 by means of screws and slotted holes (FIG. 1). The slot holes are to be dimensioned in such a way that a shift corresponding to the thickness of several imaging plates is possible ³ S. Another solution would be to adjust the axial position of the double spring 50, which can be attached to the bracket 52 by means of slotted holes (FIG. 7).

In one embodiment, the multiple curved transducer head had a radius of curvature of approximately 76 mm at the gap, at the edge continuously transitioning into a radius of approximately 25 mm. It was attached to a lever arm about 75 to 90 mm long made of spring steel about 0.25 mm thick. At a constant contact pressure of around 20p, measured with a strain gauge (Fig. 7), a uniformly close and stable contact could be established between the transducer and the imaging plate if at least 20 or more such foils rotated as an undeformed stack segment. With less than 20 4a foils, the required contact pressure was reduced almost proportionally with the number of foils in the segment. It is easiest not to use the 20 foils closest to the holding plate Aa at all. The contact pressure of the magnetic head for storing and reading out the other several hundred storage foils is then set to a uniform strength.

The double spring 50 keeps the magnetic head in a constant position (FIG. 8) with respect to the storage area, which is necessary for constant signal amplitudes during recording and reproduction. The sliding body 48 with magnetic head 44 has, for. B. the following dimensions: outer diameter 9.5 mm with a central part of about 4.8 mm in diameter and a radius of curvature of 76 mm. The read / write gap of the converter is in the geometric center. The ring-shaped edge zone is rounded with a radius of 25 mm.

The initial manual adjustment of the contact pressure of the magnetic head 44, which has already been mentioned above, is made considerably easier by the strain gauge in FIG. The latter can be connected to an oscilloscope as a monitoring element for the pressure exerted by the double spring 50 for the purpose of fine adjustment of the preload for the transducer head. The transducer is then placed in the most favorable position with respect to a test image plate, which lies in the middle of the stack of foils and may not be used for recordings. In doing so, the recorded signal patterns are monitored and the setting is changed until the best efficiency of the recording is achieved with the least amount of wear on the image plate. In the exemplary embodiment shown with foils of about 30.5 cm in diameter made of polyester, about 0.043 mm thick and coated with magnetizable oxide, once the converter has been set to a speed of 1800 rpm, it is able to hover over all imaging plates, with the exception of about the first 20 pieces that are closest to the holding plate Aa.

The extensometer can also serve as a signal transmitter for automatic fine adjustment during operation in order to vary the position of the spreading device with respect to the carriage 18 over the distance of several film thicknesses. With the resulting, differently adjustable contact pressure of the magnetic head, all memory foils including the first 20 could be queried. In order to achieve optimal results, the contact pressure could automatically be finely regulated and thus changing external influences could be compensated.

The present apparatus is also suitable for double access (Fig. 23). A second access device could either work at the same time or be kept as a reserve for another.

From Fig. 23a it can be seen that the double access can take place independently of one another, as desired postponed (in standby mode), or at the same time. With simultaneous access, the As shown in the drawing, either different or one and the same imaging plate can be achieved. The facilities would be transported on separate sleds.

23b shows another variant of double access. The two spreaders deform the Image plates in opposite directions. This allows the foils to be used on both sides will. 24 shows several stacks of foils in a coaxial arrangement be accomplished by a single unit or by multiple units. When using several access devices, it is sufficient to move them axially the use of clutches and a common drive.

According to FIG. 25, the magnetic head can also be resiliently accommodated within the cutting knife. Writing and reading takes place through an opening 91 in the knife on the storage area of the deflected film stack segment. The knife would only penetrate the rotating foil stack along the chord 69 until the magnetic head has reached the desired track. The contact pressure for the magnetic head is set here by pads which are inserted at the point where the head support is attached to the separating knife (Fig. 25). With a suitable setting and a stack of foils that rotates at 1800 rpm, the magnetic head floats with air bearings over the deflected foils. The adaptation of the magnetic head required for satisfactory quality of the recorded signals can be achieved with all storage foils with the exception of the last 50 of the right end of the stack (FIG. 2).

In addition 6 sheets of drawings

Claims (13)

Patent claims: 1. Carrier device for at least one cutting knife and at least one opposite this movable transducer in a data storage device with at least one rotating stack is more flexible Recording media whose axial distance is less than the corresponding extent for data recording or -scanning serving transducers and which can be spread apart by means of the separating knife are so that the transducer can be brought into working position with respect to a recording medium, characterized in that that the cutting knife (28) with the formation of an in particular hydrodynamic gas bearing by one-sided deflection of a part of the record carrier stack (8) creates a space, and that in this space one by means of a sliding body (48) hydrodynamically with respect to the recording medium stored converter (44) is brought into working position. 2. Carrier device according to claim 1, characterized in that the cutting knife (28) and sliding body (48) have separate actuating devices (24.25,26,32,34 and 50,52,54,68). 3. Carrier device according to claim 2, characterized in that the actuating device for the cutting knife (28) consists of a carrier (26) rigidly connected to it, which on the one hand mounted and displaceably mounted on a rod (24) connected to a frame (25) on the other hand connected to a piston rod (32) of a pneumatic pressure cylinder (34) is. 4. Carrier device according to claim 2, characterized in that the actuating device for the sliding body (48) this into the opening formed by the cutting knife (28) between introduces two recording media (8) and then in the working position just above the recording media (8) lowers. 5. Carrier device according to claim 1, characterized characterized in that the sliding body (48) is resilient on it in the axial direction of the plate stack, in particular is arranged by means of a double spring (50) composed of two parallel leaf springs. 6. Carrier device according to claim 5, characterized in that the double spring (50) on the one hand carries the sliding body (48) protruding through an opening (91) of the cutting knife (28), on the other hand is attached to the cutting knife (28). 7. Trägerervorrichiung according to claim 5 or 6, characterized in that the on the sliding body (48) exerted force is adjustable. 8. Carrier device according to claim 4 or 5, characterized in that the actuating device for the sliding body (48) from an approximately radial to the recording medium axis power-driven displaceable, straight-guided plate (54) to which the double spring (50) is attached is, and a fixed, double-armed lever (68) consists, one arm under Spring bias against a guide surface (54a) of the plate (44) is held, and by the other arm of which the sliding body (48) can be lifted off the recording medium (8). 9. Carrier device according to claim 2, characterized in that the two actuation before directions (24, 25, 26, 32, 34 or 50, 52, 54 68) for cutting knife (28) and sliding body (48] arranged together on a slide (18) which can be displaced parallel to the recording medium axis are. 10. Carrier device according to claim 1, characterized in that each recording medium stack (8) more than one cutting knife (28) and more than one sliding body (48) with converter (44) are provided. 11. Carrier device according to claim 10, characterized in that two opposite one another Separating knife (28) and associated sliding body (48) are provided. 12. Carrier device according to claim 10, characterized in that the cutting knife (28) and associated sliding bodies (48) arranged in the same direction with respect to the recording medium axis are. 13. Carrier device according to claim 10, characterized in that the cutting knife (28) and associated sliding bodies (48) arranged in opposite directions with respect to the recording medium axis are.