Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
  • B29D—PRODUCING PARTICULAR ARTICLES FROM PLASTICS OR FROM SUBSTANCES IN A PLASTIC STATE
  • B29D17/00—Producing carriers of records containing fine grooves or impressions, e.g. disc records for needle playback, cylinder records; Producing record discs from master stencils
  • B29D17/005—Producing optically read record carriers, e.g. optical discs
  • B29D17/007—Forming the relief pattern on a support larger than the record
• • G—PHYSICS
  • G11—INFORMATION STORAGE
  • G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
  • G11B23/00—Record carriers not specific to the method of recording or reproducing; Accessories, e.g. containers, specially adapted for co-operation with the recording or reproducing apparatus ; Intermediate mediums; Apparatus or processes specially adapted for their manufacture
  • G11B23/0014—Record carriers not specific to the method of recording or reproducing; Accessories, e.g. containers, specially adapted for co-operation with the recording or reproducing apparatus ; Intermediate mediums; Apparatus or processes specially adapted for their manufacture record carriers not specifically of filamentary or web form
  • G11B23/0021—Record carriers not specific to the method of recording or reproducing; Accessories, e.g. containers, specially adapted for co-operation with the recording or reproducing apparatus ; Intermediate mediums; Apparatus or processes specially adapted for their manufacture record carriers not specifically of filamentary or web form discs
• • G—PHYSICS
  • G11—INFORMATION STORAGE
  • G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
  • G11B5/00—Recording by magnetisation or demagnetisation of a record carrier; Reproducing by magnetic means; Record carriers therefor
  • G11B5/62—Record carriers characterised by the selection of the material
  • G11B5/68—Record carriers characterised by the selection of the material comprising one or more layers of magnetisable material homogeneously mixed with a bonding agent
  • G11B5/70—Record carriers characterised by the selection of the material comprising one or more layers of magnetisable material homogeneously mixed with a bonding agent on a base layer
  • G11B5/716—Record carriers characterised by the selection of the material comprising one or more layers of magnetisable material homogeneously mixed with a bonding agent on a base layer characterised by two or more magnetic layers
• • G—PHYSICS
  • G11—INFORMATION STORAGE
  • G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
  • G11B5/00—Recording by magnetisation or demagnetisation of a record carrier; Reproducing by magnetic means; Record carriers therefor
  • G11B5/74—Record carriers characterised by the form, e.g. sheet shaped to wrap around a drum
  • G11B5/82—Disk carriers
• • G—PHYSICS
  • G11—INFORMATION STORAGE
  • G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
  • G11B7/00—Recording or reproducing by optical means, e.g. recording using a thermal beam of optical radiation by modifying optical properties or the physical structure, reproducing using an optical beam at lower power by sensing optical properties; Record carriers therefor
  • G11B7/24—Record carriers characterised by shape, structure or physical properties, or by the selection of the material
  • G11B7/26—Apparatus or processes specially adapted for the manufacture of record carriers

Definitions

• This invention relates to improvements in the manufacture of data storage media and . more particularly, to an improved rigid substrate for making a rigid disk storage medium.
• a rigid disk recording medium includes a rigid substrate over the faces of which a coating of storage material, such as magnetic or optical material, is placed. Unless the substrate is properly manufactured, these flaws or defects will arise inherently, and control in the manufacture of the substrates to
• SUBSTITUTE SHEET eliminate the flaws and defects is a time consuming, high cost aspect of the overall manufacturing process.
• abrasive machining technique in which an abrasive material is applied to the faces of a substrate to eliminate the flaws or defects on such faces.
• Another technique is the so-called lathe-turning or diamond-turning technique where each substrate is rotated about its central axis and subjected to the cutting technique of a diamond tipped tool to smooth the faces and to flatten the same while removing oxides and other coatings therefrom.
• Still a. third technique is a electrochemical ma ⁇ hining- technique which subjects the faces of a rigid substrate to an electrochemical process to clean the faces and make them substantially flat and parallel with each other.
• a typical procedure in the manufacture of a substrate for use as the base of a rigid disk recording medium includes the purchase of a disk blank with a roughed inner diameter and outer diameter.
• the blank is initially directed through a double disk grinder to cause the faces of the blank to become substantially flat and to remove the oxide layer on the faces of the blank.
• the blank is directed through an edging and chamfer machine to bore the inner and outer peripheries to try to assure that the inner and outer diameters will be substantially within certain tolerances.
• the blank is then directed through a flat c u _rr ⁇ u ⁇ SHEET baking oven and subjected to 10 to 12 hours of this oven for annealing purposes.
• the blank is then put into a diamond-turning lathe, and the two faces of the blank are subjected to a reduction step by the diamond tool. After this has occurred, both faces of the blank must then be examined and inspected to assure that it contains no major flaws or defects and is within certain tolerances specified for the manufacture of a rigid disk recording medium. All the foregoing is extremely time consuming and costly and provides a limited yield at best, such as 100 to 125 blanks per hour. Moreover, not all of the flaws and defects associated with the blanks are clearly eliminated; thus, the quality of the resulting product for use as a substrate for a rigid disk recording medium is relatively low and rejections are common everyday occurrences. Flaws and defects found in conventional substrates are random and unpredictable.
• the present invention is directed to an improved substrate for use as part of a rigid disk
• the substrate is substantially free of all the flaws and defects of conventional rigid disk substrates yet the substrate of the present invention can be made at high production speeds and be of extremely high quality while assuring that the substrate will be consistent in geometry and reliability and will have high mechanical and structural integrity and strength.
• the substrate of the present invention can be made so that the faces of the substrate can have any desired texture, lay or form so that the substrate will be suitable for a wide variety of applications notwithstanding its high quality and high structural and mechanical integrity. Additional features of substrates of the present invention is that they have uniform part-to-part dimensions and consistent geometry including uniformity of surface, parallelism of faces and flatness of such faces. Each substrate is symmetrical, pre-stressed, stronger and more dimensionally stable- and with, greater integrity than substrates which require machining from rough blanks.
• Another aspect of the present invention is the provision of apparatus and a method for forming a substrate of the type described.
• Such apparatus and method allow for the high yield manufacture of the substrate in a single pass through a production line, beginning with the blanking or stamping of disks from an elongated strip of material, such as aluminum or aluminum alloy.
• the apparatus and method further include cleaning and treating the blanks as they move toward and through an embossing or coining press in which each substrate disk or blank is subjected to a high pressure, such as 1500 tons or more, to cause a cold flow of the material on the faces and within the disks, resulting in a surface on each face of extremely high quality, free of flaws, consistent and uniform in dimensions and geometry and parallelism between the
• the apparatus further includes means for packaging the coined disks in such a manner that the disks are kept free of contamination with the atmosphere, yet the disks can be immediately moved to a point of use or storage location depending upon needs for production of high quality rigid disk storage media using the coined substrates.
• the primary object of the present invention is to provide an improved substrate for use *as a part of a rigid disk storage medium wherein the substrate is formed in a coining process to provide surfaces on the substrate which are uniform in dimension and consistent in geometry with other substrates, including uniformity in surface, parallelism of faces and flatness of each face of the substrate, whereby the substrate is virtually free of flaws typically found in substrates produced by conventional diamond-turning and abrasive machining techniques yet the substrate of the present invention is of extremely high quality, can be made at high production rates at minimum cost.
• Another object of the present invention is to provide an improved substrate of the type described wherein the substrate can be fabricated with any desired surface finish, texture, lay or form yet the substrate has high mechanical and structural integrity and strength and can be made at a rate many times greater than the rate at which conventional substrates can be produced, all of which reduces the cost of production while providing a substrate of vastly improved quality over conventional substrates.
• Another object of the present invention is to provide an apparatus and a method for the high production manufacture of substrates of the type described wherein the substrates can be formed, cleaned, coined, stacked and loaded onto trays in an automatic fashion, all of which can be done at high
• Fig. la is a perspective, schematic view of the upstream stage of an apparatus for the high volume manufacture of substrates for use as parts of storage media, the view showing the way in which rolled stock material is first treated before the stock is blanked or stamped to form the disks which are used to form the substrates;.
• Fig. lb is a view similar to Fig. la but showing the next stage of the apparatus, and illustrating the way in which the stamped disks are directed out of a blanking machine and through a mechanical cleaner;
• Fig. lc is another view of the apparatus of the present invention, showing the way in which the disks are moved through cleaning tanks before being sent to an embossing press for coining of the disks;
• Fig. Id is another view of the apparatus of the present invention, showing the way in which the disks are moved out of a cleaning tank in one section of a clean room and into a final clean room section where the disks are subjected to high mechanical pressures of the embossing press to coin the faces of the disks;
• Fig. le is a view of the apparatus, showing the way in which the coined disks leave the embossing press and are placed in trays for transit through an air lock separating the final clean room from the ambient atmosphere;
• CU ⁇ 3T Fig. 2 is a top plan view of a section of the elongated stock material showing various stages of stamping the stock material to form the disks, the center hole for the disks, and the chamfers on the inner and. outer peripheries of the disks;
• Fig. 3 is a section through the stock material showing the various stages of the stamping of the disks therefrom;
• Fig. 4 is an enlarged cross-sectional view of the stock material, showing the way in which chamfers are formed by dies on opposite sides of a disk;
• Fig. 5 is a perspective view of a transfer device for feeding the disks into, through and out of the embossing press in which the disks are coined
• Fig. 6 is a section through the die of the , embossing, press, showing the way in which a disk is contained between the faces of the die for coining thereby;
• Fig. 7 is a feed mechanism for stacking the coined disks from the transfer device of Fig. 5 into the grooves of a tray disposed on a conveyor.
• the apparatus for forming coined or cold forged substrates of the present invention for use as storage media is shown in Fig.s la-le and is broadly denoted by the numeral 10.
• Apparatus 10 is adapted for forming substrates whose opposed faces are coined to present a high quality product substantially free of flaws associated with conventional substrates of storage media.
• the resulting storage medium formed with the substrate of this invention is of the type shown in Fig. 8 in which the faces of the substrate are coated with respective layers of a particular storage material and then used as a rigid disk, data storage medium.
• Typical coatings include magnetic and optical coatings to allow the storage medium to be used with magnetic and optical read-write heads for recording
• Apparatus 10 at the upstream end thereof, includes a holder 12 for mounting a roll 14 of a suitable stock material, such as aluminum, for use in forming disks which are to become the substrates of the present invention.
• a suitable stock material such as aluminum
• the stock material can be of any type which constitutes a malleable or coinable material or combination of materials, including clads and laminates.
• the stock material is in the form of a strip 16 of a standard width, such as from 7 to 9 inches. The strip is sufficiently flexible so that it can be bent and doubled upon itself so that it can be moved off and away from roll 14, past a guide post 18 and into and.
• a straightening machine 20 having a series of parallel rollers 22 which straighten the strip 16 so that it is generally coplanar between the side marginal- edges thereof.
• the strip is then moved past a second guide post (not .shown) and into and through a press 25 having a series of vertically aligned rollers 26.
• the strip passes between the center rollers 26 of the set to develop an ultra-precision thickness for the strip.
• the thickness of the stock strip is within a tolerance range of ⁇ .003 inch.
• strip 16 will have a thickness tolerance in the range of ⁇ .0001 inch.
• the purpose of this reduction in the tolerance is to have a precision volume of material presented by each disk to the coining or embossing press at a downstream location as hereinafter described. Without such precision volume in the disk, inconsistencies in dimensional and mechanical characteristics of the various disks could develop which would present problems encountered in the manufacture of conventional substrates.
• SUBSTITUTE SHEET stamping machine 30 in which a number of different stamping steps are performed.
• the stamping machine 30 can be conventional in construction and has a specific set of dies to perform the desired stamping steps.
• the end result of the stamping operation in the stamping machine 30 is a series of flat disks which have center holes and which are chamfered on the inner and outer peripheries thereof.
• a suitable stamping machine for this purpose is a 250 ton blanking machine made and sold by Minster Machine Company of Minster, Ohio.
• the machine includes a series of dies 32 only two of which are shown in Fig. lb.
• Fig. 2 shows a sequence in the stamping of a disk from strip 16 in machine 30.
• the first step occurs when strip 16 is stamped to form holes' 34 in the strip. These holes are used for receiving guide pins which advance the strip through the machine to assure • precision stamping of the disks from the strip.
• the disk 36 is also formed from the strip, the disk being integral with strip 16 only at webs 38.
• a center hole 40 is formed by stamping in the strip to form the center hole for disk 36.
• Fig. 3 shows strip 16 as it corresponds to Fig. 2 in the stamping of the disk.
• Fig. 2 further shows a disk 36 after it has been chamfered at the inner periphery and at the outer periphery thereof.
• the chamfering is achieved by the use of a pair of dies 42 and 44 (Fig. 4) , the dies having circular projections 46 which are triangular in cross-section and which form chamfers 48 and 50 at the inner and outer peripheries of the disk 36. These chamfers are adjacent to chamfer rings 52 and 54.
• the next stamping operation shown in Fig. 2 is for the purpose of removing the chamfered ring 54.
• Fig. 3 shows the center hole 40 free of such ring 54.
• the next stamping step occurs to separate the disk itself from the chamfered ring 52, such ring being held by webs 38 to strip 16.
• the strip can then be chopped into segments, such as along the line 45 (Fig. 2) , to form scrap material which is taken out of the stamping machine by way of a conveyor 47 and directed into a bin 48.
• the scrap material can be reused or sold as scrap.
• the disks 36 resulting from the stamping operation are carried out of machine 30 by a conveyor 49 and directed into an abrasive or mechanical cleaner 50 where both faces of the disks are subjected to an abrasive or mechanical cleaning treatment to remove foreign material from the faces of the disks and to reduce oxide coatings, if any, on the disks-
• the disTcs 36 are then moved by conveyor 52 out of cleaner 50 and onto a conveyor system 54 where they are oriented in. vertical planes. While in this vertical orientation, each disk becomes coupled to a moving hook 54 depending from the rail 55 of a transfer system 56, each hook having a lower end which is received in the center hole 40 of the corresponding disk 36, whereby the disk can be lifted and caused to move along the serpentine path of the rail 55.
• Transfer system 56 delivers the disks 36 in a serial fashion to a cleaning tank 60 having a number of compartments 62, 64, 66 and 68, wherein different cleaning solutions are located to progressively clean the disks as they are lowered into each compartment, then lifted up and then lowered into the successive compartments.
• the cleaning solutions remove remaining -foreign materials and oxides from the disks.
• SUBSTITUTE SHEET hooks then return to a location near conveyor 54 (Fig. lb) to pick up and transfer additional disks 36.
• a clean room section 73 defined by a top wall 75, a front wall 83 (Fig. Id), a bottom wall 77 and a pair of spaced side walls 79.
• This clean room section is constructed so that air flows out of the region 73 through the open side 71, the air flow being denoted by the arrows 80.
• a blower 82 (Fig. Id) is mounted on the upper wall 75 and blows air through plenums 77 and then into louvered passages 79 in front wall 83, whereby the air leaving the passages 79 is substantially laminar flow toward, into and through open end 71.
• the interior 73 of the clean room containing de-greasing tank 72 is substantially kept free from any foreign matter entering the clean room which would otherwise tend to enter the clean room by way of the open side 71.
• the end wall 83 in which plenums 77 and passages 79 are located has a port 84 through which conveyor 74 extends.
• the conveyor includes a static platform 86 and a reciprocal disk-advancing or feed device 88 for supporting the disks 36 and for advancing them one by one into an embossing press 90 which contains the coining dies for coining the faces of the disks. Press 90 is in a final clean room section 92 which is enclosed by wall 83, top wall 94, end wall 96 (Fig. le) and bottom wall 98.
• the air flow through the final clean room section 92 is from the louvered passages 100 in top wall 94 and downwardly into a porous floor 102 and into a plenum chamber 104 for flow of the air to a recirculating plenum.
• the air flow is directed from a blower 106 into and through passages 100 and downwardly into and through floor 102.
• Press 90 can be of any suitable construction. Typically, it can be one made by Minster Machine Company in Minster, Ohio and known as a 1500 ton knuckle joint embossing press. A machine of this type can deliver up to 100 strokes per minute.
• the feed device 88 for advancing disks 36 into embossing press 90 is a ladder mechanism operable in cooperation with static platform 86, the platform- having a plurality of posts or spindles 87 thereon, shown in Figs. Id and 5.
• Device 88 includes a pair of spaced rails 90 and 92 which move axially and transversely of their longitudinal axes. Each rail has a plurality of fingers 94 thereon which engage the outer peripheries of the various disks 36 and clamp the disks between the rails.
• the ladder mechanism is conventional in construction and is made by a number of different companies, including Minster Machine Company of Minster, Ohio.-
• the typical operation of the ladder mechanism includes the steps of moving the rails 90 and 92 " inwardly relative to and toward each other so that the fingers 94 grip the opposed side marginal edge portions of the disks on first posts 87. Then, the rails are lifted a slight amount to lift the disks off the posts. Then the rails are advanced toward the machine 90 and through a distance sufficient to align each disk with the next adjacent, downstream post 87. Then the rails are lowered, thereby lowering the disks on vertically aligned posts therebeneath, following which the rails are moved away from each other, separating the fingers from contact with the respective disks. Then the rails are moved in the opposite direction to positions at which the fingers 94 are again aligned with the next adjacent disks 36. Then the process is repeated and
• each disk 36 is advanced, there is one disk 36 which is moved into the die zone 110 (Fig. 6) of embossing press 90.
• the press has dies 112 and 114 mounted on reciprocal shafts 116 and 118, the shafts having lower and upper ends, respectively, which are chamfered to effectively receive the chamfered center hole of each disk 36 aligned therewith.
• Dies 112 and 114 have die faces 120 and 122, respectively, for engaging the opposed faces of the disk 36.
• the die further has stop members 124 which limit the travel of the die 112 toward die 114.
• die 112 The downward movement of die 112 is stopped by stop members 124 moving into engagement with each other.
• the die faces engage the faces of the disk 36, and the pressure exerted on the disk faces is of the order of 1500 tons, depending upon the- size of the disk, causing a coining or cold flow of the material of the disk, while the inner and outer diameters of the disk are contained, rendering the faces of the disk extremely smooth, flat and in parallelism with each other.
• Embossing press 90 operates at a rate of approximately 100 strokes per minute; thus, the transfer device 88 defined by the ladder mechanism 90 operates at this same speed or faster.
• each disk 36 is subjected to the contained, massive pressures of dies 112 and 114, the disk is moved progressively toward an exit port 130 in a side wall 131 of embossing press 90.
• the transfer device 88 advances each coined disk 36 to a tray loading mechanism 132 for loading the coined disks in trays 134 at a location adjacent to the side wall 131 of embossing press 90 near exit port 130 thereof.
• the trays are directed into a final clean room through an air lock 136 (Fig.
• a conveyor 138 which carries the tray, with a lid 140 thereon, into a machine 142 within clean room section 92 which removes the lid from the tray and uses that particular lid for covering a full tray of coined disks on a second conveyor 144 which extends toward and through. air lock 136.
• Each tray 134 has grooves 150 therein for receiving and supporting a stack of coined disks 36 arranged in vertical planes as shown by stack 152 (Fig. 7) .
• stack 152 Fig. 7
• the incoming, empty trays 134 are directed to a first station adjacent to a loading mechanism 132, whereupon a transfer member 154, which can be electrically, hydraulically or pneumatically actuated, pushes an empty tray 134 into a position beneath and adjacent to loading mechanism 132.
• a transfer member 154 which can be electrically, hydraulically or pneumatically actuated, pushes an empty tray 134 into a position beneath and adjacent to loading mechanism 132.
• an empty tray will be in position to receive coined disks one by one in the slots or grooves 150 of the tray aligned with and beneath mechanism 132.
• Mechanism 132 includes a box-like housing 161 (Fig. 7) having a pair of opposed, parallel sides 156 mounted on a shaft 158 for rotation in the direction of arrows 160.
• the housing- has four sliding end walls 162 shiftably mounted on sides 156, each end wall 162 having an expandable mandrel 164 thereon which is expanded by a mechanism (not shown) within housing 161 to grip and hold a coined disk 36 as housing 161 is rotated in a clockwise direction when viewing Fig. 7 through an arc of approximately 90°.
• the corresponding vertical end wall 162 having a coined disk on its mandrel is allowed to move downwardly under the influence of another means (not shown) within housing 161. This downward movement occurs until the coined disk is inserted in a corresponding groove 150 of the corresponding tray 134, whereupon the mandrel is contracted and the conveyor 144 is advanced in a direction of arrow 147 (Fig. 7) through a slight
• the process continues until a tray 134 has been filled and the tray has moved out from beneath housing 161.
• Transfer member 154 is then energized to push the next available empty tray 134 into a position beneath and vertically aligned with the housing 161.
• the full tray moves away from loading mechanism 88 and into and through the machine 142, where it receives a lid 140 taken from an empty tray traveling in the opposite direction toward zone 135.
• the machine 142 can be of any suitable construction, such as a vacuum lift including a piston and cylinder assembly 149 and a control mechanism (not shown) for actuating assembly 149 to lift off, by suction or otherwise, the lid 140 from an incoming tray and placing the lid on an outgoing, full tray.
• Conveyors 138 and 144 work intermittently and extend through the air lock 136.
• the air lock has an entry gate 163 and an exit gate 165 with reference to the direction of movement of the incoming empty trays.
• the gates are operated by fluid piston and cylinder assemblies 167 and 169 operated by control means (not shown) which are pre-programmed in accordance with the rate of coining of embossing press 90 and the incremental advancement of conveyors 138 and 144.
• the coined substrate disks in the full trays are not exposed in any way to the ambient atmosphere. They are taken to a job site and into clean rooms for receiving coatings on the
• Fig. 8 shows a completed disk with a layer 170 of material thereon, such material being sufficient -to provide a storage capability for the disk.
• the coating is a magnetic coating which is applied in any conventional manner.
• the coat material could also be suitable for optical recording as well as audio, video and computer recording.
• apparatus 10 is first provided with a roll 14 of material, such as aluminum or aluminum alloy, in strip form.
• the strip 16 is then initially fed into the straightener machine 20, then through the press machine 25 where the thickness of the strip 16 is controlled within a tolerance range of ⁇ .0001 inch.
• the strip is then fed through the blanking machine 30 in which the individual disks 36 are formed, the scrap from the blanking or " stamping operation being directed into a bin 48 for reuse or for sale.
• the disks 36 are then moved into and through the cleaning machine 50, then out of the machine and into coupled relationship with hooks 54 on conveyor 56.
• the disks are then directed into the various compartments of cleaning tank 60, then out of the tank, through dryer 70, and then into de-greasing tank 72 for the purpose of cleaning the disks prior to their being coined in embossing press 90.
• the disks are then separated from hooks 54 and then become coupled to the transfer device 88 for transit successively into, through and out of embossing press 90 in which the disks are coined.
• Fig. 6 illustrates the way in which the dies 112 and 114 are shifted relative to each other and into engagement with the opposed faces of the disks 36 to coin them.
• the pressure exerted by press 90 is of the order of 1500
• the disks are coined, they are moved out of press 90 by transfer mechanism 88 and become coupled with transfer mechanism 132 so that the coined disks are fed one by one into a tray 134 below mechanism 132 and movable by conveyors 138 and 144.
• the coined disks eventually fill each tray and the full trays are moved incrementally by conveyor 144 through machine 142 where the full tray receives a lid and then is moved out of the final clean room 92 through an air lock 136 and then to a location at which the encased coined disks are stored or put into actual use.
• the present invention provides for the economical and high yield manufacture of high quality substrates for use as data storage media by coining.
• the invention further includes apparatus and a method for making the substrate.
• the substrates made in accordance with the teachings of the present invention have uniform part-to-part dimensions and consistent geometries, including uniformity of surface texture, parallelism of the faces of the substrate and flatness of such faces.
• the substrates of the present invention are virtually free of all flaws typically found in substrates produced by diamond-turning and abrasive machining.
• the substrate of the present invention improves both product quality and thereby minimizes the amount and degree of inspection tests following manufacture.
• the substrate of the present invention can also be provided with any desired surface finish, texture, lay or form. This feature could include but is not limited to cross-hatch, radial, circumferential and random lays. This is achieved by selecting the desired finish, texture, lay or form of the die faces which contact the faces of each disk 36 in the manner shown in Fig. 6.
• the substrate of the present invention eliminates the problem of asymmetrical stresses associated with other substrate fabrication techniques.
• the substrate of the present invention is symmetrical throughout its entirety, is symmetrically pre-stressed, and is stronger and more dimensionally stable and has greater structural integrity than those conventionally machined from solid parts.
• the substrate of the present invention further exhibits sub-micron flatness and smoothness and has exceptional axial acceleration characteristics in dynamic functions.
• the substrate of the present invention can be produced from high purity, corrosion-resistant aluminum materials (al-clad) that are not adaptable to conventional fabrication techniques.
• the substrate of the present invention is made such that it needs only a minimum amount of nickel undercoating currently required in post-processing of conventional substrates.
• the substrate of the present invention can be thinner than conventionally produced substrates and still be a high quality product.
• the substrate of the present invention can be produced at much greater production rates per manufacturing station than conventionally produced substrates.
• conventional techniques provide for maximum production rates at best of no more than 100 to 125 substrates per hour.
• the present invention when in operation, can produce as many as 4800 to 6000 substrates per hour so as to have a throughput over 40 times as fast as conventional techniques.
• the present invention provides higher manufacturing yields than is capable with conventional techniques of producing substrates.
• the substrate made in accordance with the present invention improves yields in post-processing media applications and in disk drive assembly and qualification.
• the coined substrate of the present invention minimizes the effect of impurities of the malleable material on surface finish and product functionality. Less scrap material is generated and fewer production and inspection operations are necessary in the manufacture and quality control of the substrate of the present invention.
• the substrate of this invention can be fabricated with special features, such as index and timing marks and integral spacer rings 200 (Fig.. 8) which simplify the disk drive assembly process by reducing the number of parts and part interfaces, thereby minimizing tolerance build up.
• the substrate of this invention can use a number of different preforms including blanked, forged, extruded, sintered and rolled material forms.
• the substrate ' can be fabricated by the use of compensated dies that account for the expansion characteristics of given materials.
• the substrate can be fabricated with precision chamfers and other unique features, including tapered substrates for low inertia systems.

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• Manufacturing & Machinery (AREA)
• Manufacturing Of Magnetic Record Carriers (AREA)
• Casting Or Compression Moulding Of Plastics Or The Like (AREA)

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• 1985
  • 1985-06-19 AU AU45404/85A patent/AU4540485A/en not_active Abandoned
  • 1985-06-19 JP JP60502892A patent/JPS61502787A/ja active Pending
  • 1985-06-19 KR KR860700137A patent/KR860700307A/ko not_active Application Discontinuation
  • 1985-06-19 EP EP19850903528 patent/EP0188523A4/en not_active Withdrawn
  • 1985-06-19 WO PCT/US1985/001182 patent/WO1986000741A1/en not_active Application Discontinuation
  • 1985-06-28 CA CA000486083A patent/CA1254300A/en not_active Expired
• 1986
  • 1986-03-05 DK DK100086A patent/DK100086A/da not_active Application Discontinuation

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