DE1953079A1 - Lamella plate for magnetic disk storage or the like. - Google Patents

Description

BURROUGHS CORPORATION, incorporated under the laws of the Michigan State, Detroit 32 «Michigan State (V.St.A.)

Lamellar plate for magnetic disk storage or the like.

The invention relates to a low-vibration lamellar plate for rotating plate systems, in particular for Magnetic disk storage.

In the construction of many mechanical systems, one must strive to control the vibrations to which the individual elements of the system are exposed. Venn the vibrations on the one or the other type is not sufficiently damped and / or the natural frequencies of the individual elements are not sufficiently far removed from the frequencies of the vibrational forces to which they are exposed, the operation of the system is impaired by resonance in a natural frequency of one or more elements or, in the worst case, the entire system is destroyed.

009827/1881

A mechanical system in which the vibrations are dominated must be, for example, a magnetic disk storage. In the case of magnetic disk storage, information is stored on the magnetic surface of large rotating disk systems stored. Access to the magnetic surface takes place in that the flattening system is driven so that it rotates past a magnetic head which is in the Attached near the magnetic surface of each plate. To get a maximum value for the ratio signal To get house of the electrical system, the magnetic head gets as close as physically possible to the magnetic one Surface arranged without touching it. Therefore, a design requirement is the vibrations of the disk system to the lowest possible value, so that the magnetic head closer together the magnetic surface can be arranged. Unfortunately, some other constructs favor tion requirements of a plate system large vibrations of the plates. E.g. about the storage capacity of the disk to increase, it is desirable to make their diameter very large; the access times to each area To keep the plate as short as possible, it is desirable to keep the plate at high angular velocity to propel; and in order to reduce the weight and amount of the plate material, it is desirable to have the Make the plate as thin as possible.

According to the invention, a rotating disk for a magnetic disk storage device or the like is proposed which consists of consists of several »disk-like lamellae, the surfaces of which close together. The abutting surfaces of the lamellae are in this way with one another

Contact held that they are relatively in a small part of their contact area near the center of the plate are fixed to one another and can be moved relative to one another over the rest of the contact surface. It has shown that this arrangement has a high internal damping for vibrations to which the element is exposed is. The interface between the lamellas destroys part of the energy in their helative movement plugged. As a result of the energy dissipation at the interface, potential vibrations of the plate, in particular axial vibrations, dampened. The separating surface is preferably formed in that the two disc-like lamellae are so clamped that never touch each other intimately at rest, but relative to each other over most of their contact area are freely movable. In a dimensional grid system, the disc-like slats can be converted into are clamped in their middle between mounting hubs. One or both of the non-touching The surfaces of the disc-like lamellae are coated with a magnetic material.

In one embodiment according to the invention, a disk-like lamella has a largely smaller diameter than the other. In another embodiment of the invention, the two have disk-like shapes Lamellae largely the same diameter. This is the interface and thus the ability to destroy energy, great.

In a further embodiment according to the invention, a plate consists of three disc-like lamellae, whose surfaces lie against one another. Preferably one is

009827/1881

0AD

disk-like lamella with a large diameter sandwiched between two disks with smaller ones Arranged diameters. The facing surfaces of the smaller disc-like lamellae are in Resting state in intimate contact with the opposite surfaces of the larger disc-like lamella. The smaller lamellae are used, the larger lamellae without a corresponding increase in the total weight to stiffen the plate. As a result, the natural frequencies of the plate are higher than the natural frequencies of the individual ones Lamellae that make up the plate. By increasing the natural frequencies, the plate can move at higher angular velocities operated without reaching the lowest natural frequency. Additionally destroy the Separation surfaces between the lamellas energy, so that potential vibrations of the plate are dampened. One or both surfaces of the large disk-like sipe are coated with a magnetic material.

The invention is explained in detail below with reference to the embodiments shown in the drawings. It shows:

Jig. I a partially cut, side Elevation of an embodiment of a plate according to the invention;

FIG. 2 is a fragmentary front view of the embodiment of FIG. 1; ·

Figure 3 is a side elevation of another embodiment of the present invention Plate.

1 shows a drive shaft 1 which is mounted in a stationary frame 2 with the aid of bearings 3 and 4 is. The shaft 1 is coupled to a motor 5. on

009827/188 1

the shaft 1 has two circular hubs 6 and 7 attached. Two circular, disc-like lamellae 8 and 9 with the same diameter are attached to the shaft 1 between the hubs 6 and 7. The surfaces facing each other the lamellas 8 and 9 are lapped so that they are flat and able to touch each other intimately, but without being physically connected to each other. The non-touching surfaces of the slats 8 and 9 have coatings 10 and 11 made of a magnetic material such as iron oxide so that they store information can. Both the hubs 6 and 7 and the lamellas 8 and 9 have central bores whose diameter is slightly larger than the diameter of the Shaft 1 so that they fit properly when they are mounted on shaft 1.

The hubs 6 and 7 are clamped together with the aid of bolts and nuts 20, 21, 22 and 23 and according to FIG. 2 with Fixed to the shaft 1 with the help of pins 24 and 25. The pins 24 and 25 prevent the hubs from rotating 6 and 7 relative to the shaft 1. The hubs 6 and 7 keep the lamellas 8 and 9 in close contact when they move are at rest. The facing surfaces of the slats 8 and 9 are in the part of their contact surface, which is located directly between the hubs 6 and 7, positively driven, i.e. they are relative to each other held stationary. As a result, the positively guided part of the contact surface is created by the diameter of the hubs 6 and 7 determined, which is largely smaller than the diameter of slats 8 and 9 * The slats 8 and 9 are over the remaining part of their contact surface free, i.e. they have no contact relative to one another. The magnetic head 27 is close to the coating

009827/1881

ßAD ORIGINAL

the lamella 8 arranged. A similar magnetic head (not shown) can close to the coating 11 of the lamella 9 can be arranged. According to US Pat. No. 3,310,792, the magnetic heads float on the film of air produced by the rotating Plate is formed. Since the slats 8 and 8 are driven by the motor 5, they are vibrations exposed. The freedom of movement of the mutually facing surfaces of the slats 8 and 9 relative to one another in most of their contact area this results in high internal damping of these vibrations.

The construction principle of the plate according to FIG. 1 is the Formation of an energy-destroying interface between two adjacent lamellas. Preferably have the Lamellae largely the same diameter, so that the interface reaches a maximum and the energy dissipation is as large as possible. However, an effective energy dissipation still takes place if one of the Lamellae has a largely smaller diameter than the other lamellae. In the embodiment according to In Fig. 1, this separation surface is formed in that the adjacent surfaces of the lamellae are pressed against one another in this way that they are in intimate contact at rest, but over the greatest Part of their contact surface are free of movement relative to one another. However, other types are also in accordance with the invention of separating surfaces possible, which destroy the energy of the disc-like lamellae.

In an alternative embodiment of the plate according to the invention, there is a surface of a circular, disc-like lamella 30 with a small diameter in intimate contact with part of a

009827/1881

Surface of a circular, disc-like lamella

31 with a large diameter while the disk is at rest. A surface of a circular, disc-like lamella 32 with a small diameter is in intimate contact with part of the other surface of the lamella 31 · The touching ones Surfaces of the lamellas 30, 31 and 32 are lapped. The lamellae 30, 31 and 32 are similar to the plate in Fig. 1 between circular hubs 33 and 34-on a drive shaft 35 clamped so that the lamellae in part of their contact surface relative to one another are positively guided and free of movement relative to one another in the remaining part of their contact surface are. The surfaces of the lamella 31 have coatings 36 and 37 made of a magnetic material that the storage of information on the lamella 31 allows.

The lamellae 30 vaiu 32 stiffen the lamella 31 without a corresponding increase in the total weight of the rotating plate which must be driven. As a result, the core frequencies of the rotating plate are largely increased above the natural frequency of the lamella 31 alone. 7AiBPtZIiCh destroy the separating surfaces between the lamellae · 5C * inö 31 and between the lamellae 31 and

32 energy, 00 that potential vibrations are dampened. Invention principle of the embodiment according to FIG. 3 is a rotating plate made of at least three disk-like lar-ells which are arranged in such a way that the stiffener is ⁴ ; 3er? · * Sulting plate is enlarged more than iLr corresponding weight. Although in the Ausführungsufip- ίοχτη according to FIG. 3, this result is achieved in that a disk-like lamella with a

00982 7/1881

8AD ORIGINAL

- ο -

large diameter between two disc-like lamellae is clamped like a sandwich with small diameters, other constructions are possible according to the invention, the achieve the same result. For example, the three lamellas could all have the same diameter. In summary, this principle of the invention consists in the simultaneous application of two techniques, the To control vibrations in a rotating disk of a magnetic disk storage or the like: Magnification the stiffness to a greater extent than the weight, so that the natural frequencies are increased, and formation of a energy-destroying interface that dampens potential vibrations.

A convenient alternative embodiment of the invention is a single disc-shaped lamella with a small diameter, that with a single disc-shaped Lamella having a large diameter is held in contact, i.e. the plate of Fig. 3, however without the lamella 30. This embodiment is easily, without major changes in existing disk storage applicable.

In the embodiments according to FIGS. 1 and 3, the Plates and hubs are preferably arranged coaxially to the shaft on which they are attached «

009827/18 81

BATH ORIGINAL

Claims (1)

Claims Q ₅ ; Rotating element, characterized by first (8; 31) and second (9; 32) plates each with a flat surface, which are held together in such a way that they are fixed relative to one another in their center and that they are freely movable relative to one another at their peripheries . 2. Rotating element according to claim 1, characterized in that the flat surface of the first Plate (8; 31) opposite surface of the first plate (8; 31) a coating (10; 36) of a magnetic material, so that information can be stored on it. 3. Rotating element according to claim 1 or 2, characterized characterized in that the first plate (31) has a diameter which is substantially larger than the diameter the second plate (32). 4. Rotating element according to one of claims 1 or 2, characterized in that the first plate (8) and the second plate (9) largely have the same diameter own" 827/18 $ ^ - .ν- * 8AD ORIGINAL 5. Rotating element according to one of claims 1 or 2, characterized by a third plate (30) which with the first plate (31) and the second plate (32) is held together in such a way that they are in their center is fixed relative to the first plate (31) and is free at its periphery relative to the first plate (31) "is movable, the diameter of the second plate (32) and .the third plate (30) being largely smaller than the diameter of the first plate (31) 6. Rotating element according to one of claims 1 to 5, characterized in that the first (8; 31), the second (9; 32) and the third (30) plates are thereby be held together so that they are close to their centers are clamped between two hubs (6, 7 »33, 34), whose diameter is largely smaller than the diameter the first (8; 31), the second (9; 32) and the third (30) plates. 7. Rotating element according to one of claims 1 to 6, characterized in that the plates (8, 9; 30, 31, 32) have coaxial, circular peripheries; and that the flat surfaces in a circular area coaxial with the peripheries, relative to each other are fixed. 8. Magnetic disk storage with a shaft (1; 35) »which is rotatably mounted, and with a motor coupled to the shaft (1; 35), characterized by a first plate (8; 31) which is on the shaft (1; 35 ) is attached and has at least one flat surface} and by a second plate (9; 32) which is attached to the shaft (1; 35) and at least one flat surface 00982771884 - Ii - that sits on the flat surface of the first plate (8, 31) is adjacent; and by means (6, 7j 33, 3 * 0- »the the adjacent surfaces of the first plate (8; 31) and the second plate (9; 32) so in mutual intimate contact holds while they are at rest that they are relatively over most of their contact area are freely movable to one another; and by a coating (10; 36) of magnetic material on one of the non-adjacent surfaces of one of the plates (8; 31)} and by a magnetic head (27) which is arranged close to the magnetic coating (10; 36) so that Have information saved on it. 9 · Magnetic disk storage according to claim 8, characterized in that that the adjacent surfaces of the plates (8, 9; 31, 32) in a narrow, circular Area around the shaft (1; 35) are fixed relative to one another. 10. Magnetic disk storage device according to one of claims 8 or 9t characterized in that the holding means (6, 75 33, 34) have first and second flanges (6, 7; 33, 34), the opposite sides of the first, and rver "ί / e-n plates (8, 9; 31, 32) on the shaft (1; 35) are arranged; and that the flanges (6, 7; 33, 34) have smaller Dut-chia eaters than the discs (8, 9; 31, 32) and equipped with means (20, 21, 22, 23) are, with the help of which the flanges (6, 7; 33, 34-.) are clamped together with the plates (8, 9; 31, 32) in between throw. 009827/188 1 BAÖ 11. Magnetic disk storage according to one of claims 8 to 10, characterized in that the plates (8, 9; 31, 32) and the plansche (6, 7; 33, 34) circular and are arranged coaxially with the shaft (1, 35). 12. Magnetic disk storage according to one of claims 8 to 11, characterized in that the first disk (8) and the second plate (9) have largely the same diameter. 13. Magnetic disk storage according to one of claims 8 to 11, characterized in that a third plate (30) is arranged with at least one flat surface on the shaft (35); and that the holding means (33, 34) the adjacent surfaces of the first plate (31) and bring the third plate (30) in the rest position in intimate contact with one another that they over most of the contact surface are freely movable relative to one another. 14. Magnetic disk storage according to claim 13, characterized in that the first plate (31) has a largely larger diameter than the second Plate (32) and the third plate (33). .15 · Lamella plate for magnetic disk storage, characterized by a first disc-like lamella (8); and by a second disk-like lamella (9) largely the same diameter as the first lamella (8), one surface of which becomes a surface the first lamella (8) is arranged adjacent} and by a separating surface between the lamellae (8; 9), the is capable of destroying energy; and by one 00982771 * 81 Coating (10) made of a magnetic material the non-adjacent surface at least one of the Lamellas (8). 16. Lamellar plate according to claim 15, characterized in that that the interface between the lamellae (8, 9) is formed by means (6, 7) which the neighboring Hold the surfaces of the lamellas (8, 9) together in such a way that they intimately touch each other in the booth position, however are freely movable relative to one another over most of their contact surface. 17. Lamellar plate for a magnetic disk storage, characterized by a first disc-like lamella (31); and by a second disc-like lamella (32), one surface of which is on a surface of the first Lamella (31) rests; and by a third disc-like lamella (30), one surface of which is against the other The surface of the first lamella (31) rests; and by a coating (36) made of a magnetic material, which is attached to at least one surface of a lamella (31); and by means (33 »34-)» which hold the slats (30, 31, 32) together in such a way that between they create energy-destroying interfaces. 18. Lamella plate according to claim 17, characterized in that that the lamellae (30, 31, 32) are shaped so that the second lamella (32) and the third lamella (30). have a diameter which is largely smaller than the diameter of the first lamella (31); and that the first, second and third blades (31, 32, 30) are coaxial are arranged to each other. 009827/1881 BAD ORfGiNAt 19. Lamellar plate for a magnetic disk storage, characterized by a first disc-like lamella (31) having a first surface; and by a second disc-like lamella (32) with a second surface, which is disposed adjacent the first surface; and by an interface between the first and the second surface that is capable of energy to destroy; and by a coating (36) of magnetic material on one of the non-adjacent ones Surfaces of at least one of the lamellae (31). 20. Lamella plate according to claim 19, characterized in that the magnetic coating (36) located on the first lamella (31); and that the second lamella (32) is largely smaller than the first lamella (31). 009827/1881