Field of the Invention

This invention relates to data cartridge tape drive assemblies for use with incfeαstry standard capstan driven magnetic tape data cartridges used for storage and retrieval of computaticxial data. In particular, the data cartridge tape drive assembly of this invention provides positive positioning and locking of the data tape cartridge in pla-ce while maintaining ease of inserting and removing the cartridge.

Background of the Invention

Magnetic tape data .cartridges have the capability for high data capacity and are easy and convenient to use for many computer applications. ^Q aiputer equipment using such data cartridges are equipped with a tape drive system or assembly that accepts the cartridges, positions them for reading or recording, and permits removal of the cartridges. She data cartridge drive system has become accepted as a utilitarian storage system by major portions of the computer industry. Not only are ccπpiter systems becoming cartridge-equipped, but so are a great many auxiliary and supportive system devices.

Data cartridges supply good performance and reliability. Data cartridge design permits accurate reading and writing of digital data, repetetively and rapidly. Total encapsulation of tape in the cartridge provides superior tape protection frcm ^■ dropout producing dust, debris and fingerprints. Rigid base plate, captive and controlled enclosure of tape and precise tape guidance system assure excellent mechanical alignment. Size, packaging and design combine to make this medium tolerant to the potentially rougher care by users unskilled in handling coπpiter media and in less-tϊian-ideal environmental conditions.

The following types of systems - lώnico puters for machine control, data logging for sensor-based systems, word processing, key-to-tape storage for terminals, source data in inventory

control - all have one functional need in ccsrmon, i.e., a removable storage system. Further, general requirements for these systems are that the data storage media be small, inexpensive, interchangeable, and easily inserted in a lew-cost drive.

Typical magnetic tape data cartridges, such as the DC 100A and DC 300A 3M Ganpany data cartridges have the capability of high ■data capacity, are compact in size, have compact drive ass ^a emblies, are reliable and are easy and convenient to use for many data processing and data storage and retrieval applications such as computer mass storage. The physical dimensions of such data cartridges have been standardized. Computer .and other <3ata proce-ssing equipment using such data cartridges are equipped with a tape drive that accepts insertion of a data cartridge, positions the data cartridge for reading or recording, and allows remσv-al of the data cartridge in order to make the tape drive available for another interchangeable data cartridge. The tape drive assembly must provide repeated reliable interf ce with the data cartri(3ge both mechanically and electrically.

Known data cartridge tape drives are deficient for reliably and repeatedly mechanically positioning the data tape cartridge for good electrical interface, i.e., reading and recording of data, or if they do positively position the cartridge, the cartridge is difficult to remove frcm the tape drive because of the high holding force used for secure positioning. Some tape drive designs provide a locking force release device that is actuated by a push button. The mechanism of such a lodcing force release device adds to the size, cost, and complexity of the design.

Ωius, it would be desirable to have a single tape drive •assembly for data .cartridges that would positively, repeatedly, and reliably position the data cartridge in a single manner for accurate mechanical and electrical interface with the tape drive while maintaining the ease of inserting and removing the data cartridge. Suitltiarv of the Tnvpni-inn

The present invention provides a drive assembly for a

ccnguter data tape cartridge that has positive positioning, seating and locking of the tape cartridge in its operating or interface position to provide reliable mechanical contact with switches and positive motor capstan drive contact with the tape cartridge drive wheel, while permitting ease of inserting and removing of the cartridge. The cartridge tape drive of this invention is compact and single in overall construction having few total parts and even fewer moving parts, thus presenting minimal manufacturing tolerance problems.

In accord with the present invention a cartridge tape drive assembly for receiving a cartridge containing magnetic tape, locating said cartridge in a fixed operational position, and moving said magnetic tape within said cartridge, comprises:

A. locating means for receiving and positively locating a data tape cartridge in an operating position;

B. drive means for contacting said data tape -cartridge to transport magnetic tape within said data tape cartridge;

C. input-output means for reading information from or placing information on said magnetic tape; and

D. control means for detecting the presence of a data tape cartridge in said drive assembly and for controlling the input and output modes of operation of said input-output means;

Ε. said locating means comprising a pair of non-movable reference .surfaces at right angles to each other for cooperating with -said data cartridge and means for urging said data cartridge into contact with said reference surfaces.

In one embodiment the cartridge tape drive assembly of the present invention, comprises a baseplate having cartridge guide means for guiding the insertion of a data tape cartridge into said tape drive assembly; said g.uide means providing seating and positioning surfaces for said data tape cartridge to guide the data tape cartri-dge into its operating position and lock said data tape -cartridge in said operating position; spring means for resiliently applying force against the data tape cartridge to contact the cartridge against said seating and positioning surfaces; drive means for driving the tape in said data tape

cartridge, said drive means including a drive capstan; said drive capstan being resiliently urged into contact with said data tape cartridge for driving the tape contained therein; a magnetic tape read/write head for reading from and recording magnetic data onto the tape; -and control means for selecting and controlling the function of the readwrite head; wherein said cartridge guide means comprises a pair of channels, one located on each side of said baseplate, opening inwardly toward each other for receiving the edges of the base of the data tape cartridge, the top and bottom surfaces of each channel being substantially parallel, except at the innermost end of said channels wherein one surface converges toward said baseplate to narrow the channels and to provide said positioning surfaces to positively seat the .data tape cartridge in its operating position and to prevent outward movement of said cartridge when seated in its operating position.

Thus, the data cartridge tape drive of this invention provides positive positioning and lodcing of the data cartridge in place in a stable mechanical and electrical interface position while maintaining ease of inserting and removing of the cartridge. In a preferred embodiment, the invention further provides means for placing and interfacing of the control means, including the write/protect and cartridge present switches, with a data cartridge to accomodate adequate over-trav-el of the .switch actuators, thus achieving positive switch contact and obtaining control switching reliability.

Another embodiment provides a spring loaded pivot arrangement for the motor/drive capstan/shaft encoder disc assembly that assures full face to face contact of tape drive capstan with data cartridge drive wheel to maintain reliable and accurate tape movement. Ωiis also allows a single ended and shorter motor drive shaft extension in which the drive capstan is positioned closer to the near side motor s.haft bearing for less side torque on the bearing and therefore greater motor bearing life, and which also allows the motor shaft encoder disc to be placed cxi the same end of the motor shaft as the drive capstan and adjacent to the capstan in a compa-ct arrangement. Ωiese

iπprσvements result in greater reliability, lower cost and a more compact size data cartridge drive assembly.

Brief Description of the Drawings

Fig. 1 is an electro-mechanical block diagram for the data cartridge tape drive in accord with the invention.

Fig. 2 is an isometric view of a data cartridge tape drive assembly in accord with one embodiment of the invention.

Fig. 3 is a plan view, partially cut away, of the tape drive assembly of Fig. 2 illustrating the outline of a tape cartridge inserted into the -drive assembly.

Fig. 4 is a cross-sectional left side view, partially cut .away, of the tape drive assembly of Fig. 2.

Fig. 5 is a cross-sectional left side view, partially cut •away, of the tape drive assembly of Fig. 2 illustrating a tape cartriadge inserted therein.

Fig. 6 is a cross-sectional left side view of the tape drive assembly of Fig. 2 illustrating the position of a tape •cartridge for removal from the drive assembly.

Fig. 7 is a partial isometric view of a typical tape cartridge having a rectangular cutout in the edge of the base plate near the forward end of the cartridge.

Fig. 8 is a bottom view of the drive aasse bly of Fig. 3.

Fig. 9 is a partial ^' front view of the drive assembly of Fig. 8 along line 9-9.

Description of the Invention

The pres-ent invention provides a single and compact drive assembly for a data cartridge and has positive and accurate positioning, seating, and locking of the tape cartridge in its operating or interfa-ce position to provide reliable mechanical contact with the data cartridge presence and read/write switches and has positive motor capstan drive contact with the tape cartridge drive wheel, while permitting ease of insertion and removal of the data cartridge.

The data cartridge tape drive of this invention is

compact, is simple in overall construction, has few total parts, and has very few moving parts. This simplicity in construction results in lower cost, in the elimination of many tolerancing and fitting problems in manufacture and assembly, in easier and faster manufacture, in a more compact device, .and in a more reliable product.

The cartridge tape drive ass-embly of this invention will now be described with particular reference to one -embodiment of the invention as illustrated in the accompanying drawings.

The cartridge tape drive assembly 10 as illustrated in Fig. 2, is adapted to receive a .standard magnetic tape data cartridge 15 such as that illustrated in Fig. 7. Typically, such data tape cartridges 15 comprise a rectangul-ar cover 25 on a ba.se plate 21 having a rectangular cutout 22 on each side of the cartridge base plate. A recessed surface 24 on each side of the cartridge cover 15 exposes part of the rigid baseplate 21 and provides a means for guiding the cartridge by using the expo-sed edges and surfaces of base plate 21 to cooperate with the structure of the tape drive assembly when inserting the cartridge 15 into tape drive assembly 10. .Such data tape cartridges are described in more detail in, for instance, D.S. Patent No. 3,692,255, which is hereby incorporated by reference.

The cartridge data tape drive assembly 10 comprises a base plate 30 hav.ing a beveled leading edge 31 to facilitate insertion of a data tape cartridge 15. Edge guides 34 and 35 are provided on each side of the data tape drive assembly to provide reference surfaces to guide the tape cartridge into position for interface with the tape driven capstan 50 and the readwrite head 40. The edge guides .34 and 35 together with the tape drive assembly base plate 30 form channels or recesses into which the edges of the cartridge base plate 21 are inserted. The lower surface 36 of the edge guide 34, i.e., the upper interior surface of the channel facing the tape drive assembly base plate 30,.forms one reference surface and is parallel to the .surface of the tape drive assanbly base plate 30 until the rearward end of the edge guide where the •surface declines and converges toward the tape drive assembly base

plate 30 forming an angled surface 37 that is continuous with surface 36-of edge guide 34. The end of the edge guide forms a second reference surface 38 which is perpendicular to reference ■surface 36. Edge guide 35 is similarly constructed. Adjacent to edge guides 34, 35 are limit stops 41 and 42 which limit the travel of the tape cartridge 15 when inserted.

Bearing surfaces 44 and 45 are resiliently mounting in tape drive assanbly base plate 30 and preferably have a curved surface that protrudes above the surface of the tape drive assanbly base plate 30 (functioning in a manner similar to a cam ⁾ to urge the upper surface 78 of the data cartridge base plate 21 of the .data tape cartridge into contact with the lower surf ces of the edge guides 34 and 35, e.g., surface 36 of edge guide 34. The bearing surfaces AA, 45 are positioned by means of leaf springs 46 and 47 which are fastened to the bottom of the tape drive assembly base plate and support the bearings in circular openings in base plate 30.

Electrical limit switches 51a and 51b are mounted onto tape drive assanbly base plate 30 by means of structure 52 and positi-oned so that levers or actuators 55a and 55b are activated ty data tape cartridge when inserted into its operating position in the tape -drive assanbly 10. When the c3ata tape cartridge 15 is inserted into the tape drive assembly 10 and fixed in its operating position, levers 55a and 55b are selectively contacted by the cartridge and moved in a plane perpendicular to the tape drive assembly baseplate 30 to actuate switches 51a and 51b, respectively. Levers 55a and 55b are ccnvaieπtly positioned on an angle to baseplate to obtain positive control of the switch tolerance band thereby accoroodating over-travel and providing reliable contacts.

A drive motor 60 is mounted on the bottom of tape drive assanbly baseplate 30 and the drive shaft 62 projects through the tape drive assembly baseplate 30 so that the drive capstan 50 and the encoder wheel 65 are positioned above the tape drive assembly baseplate 30. Photoelectric sensing device 66 is positioned to monitor the slits in the encoder wheel 65 by means of structure

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67.

The drive motor 60 is attached to the tape drive ass-embly baseplate 30 by mounting structure 63 that can pivot about pin 70. Rod 72 extending from motor mounting structure 63 is resiliently atached to tape drive baseplate 30 by means of spring 75 that is attached at pin 77.

The mechanical operation of the tape drive assembly 10 is illustrated in Figs. 4 through 7. The data tape cartridge 15 in general use is rectangular in shape and relatively thin. The cover 25 of the cartridge 15 is recessed along each side to ejcpose the edge of the cartridge base plate 21. ϋSie exposed edges of the base plate .21 fit into the channels formed by edge guides 34 and 35 and the tape drive assβώly base plate 30. Ωie edges of the cartridge base plate 21 axe used for guiding, positioning and retaining the cartridge 15 in the tape drive assembly 10.

When the data tape cartridge 15 is inserted into the tape drive assembly 10, the beveled edge 31 of the tape drive base plate 30 aids the edges of the cartridge base plate 21 to enter the .channels formed by edge guides 34 and 35 and tape drive assembly base plate 30. One .edge of the data cartridge base plate 21 slides along reference .surface 36 as the cartridge baseplate slides over bearing surface 45 which recedes into the tape -drive assanbly base plate 30 but maintains pressure against the cartridge base plate 21 and urges the cartridge base plate 21 against reference surface 36 due to the resilient force of leaf spring 47. The leading portion of the edge of the cartridge baseplate 21 then slides along the declining surface 37 until the rectangular-shaped opening 22 near the leading edge of the cartri<3ge passes the perpendicular reference .surface 38 whereupon the inner surface 78 of the cartridge baseplate 21 snaps uprard against reference surface 36 due to the urging by bearing surface 45.

When the inner surface 78 of cartridge baseplate 21 snaps into parallel -contact with edge guide surface 36, the cartridge tape drive wheel 27 is in -contact with tape drive capstan 50 which is urged into contact with drive wheel 27 by spring 75. She

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resilient force provided by spring 75 limits the travel of the cartri-dge into the tape drive assembly and urges the data •cartridge into contact with the second reference surface 38. Limit stops -41 and A2 prevent the data tape cartridge 15 from being jammed into too far into the drive assembly 10 and thus causing damage to the magnetic read/write head 40 or the switches 51a and 51b. When the data cartridge is inserted in the drive ass-embly, levers 55a .and 55b of .switches 51a and 51b are selectively engaged and activated by the data cartridge body at the contact area. A cutout is generally provided so that one lever can remain unactivated and prevent erasure or write-over of the tape. In Fig. 7, this function is accomplished by slider 29 which permits selective activation of the switches or activation of both switches. When the cartridge 15 is in its operation positioning, the magnetic read/write head 40.

As can be readily seen be referring to the Figs, and particularly Figs. 3 through 5, the structural relationship between rectangular opening 22 in the cartridge baseplate 21 and reference .surfaces 36 and 38 of the edge guide 34 positively retains or locks the data cartridge 15 in the drive assembly 10 and the urging of the drive capstan 50 against drive wheel 27 by motor spring 75 keeps the forward edge 80 of the rectangular •opening 22 in the cartridge baseplate 21 in contact with reference surface 38. Auxiliary resilient means operating directly on the cartridge housing can be used to assist motor spring 75 to retain the data cartridge in operating position against reference surface 38 while permitting the use of lighter contact force between the drive wheel 27 and drive capstan 50. Such auxiliary springs can be conveniently mounted by those skilled in the art.

However, the cartridge 15 can be easily removed from the drive assembly 10 by lifting upwardly cn the outer end of the cartridge and simultaneously pulling the cartridge oat (Fig. 6). As illustrated in Fig. 6, this motion allows the forward edge 80 of the rectangular opening 22 in the edge of the baseplate 21 to ^■ dear edge guide surface 38 and the cartridge can be withdrawn with ea.se. No retaining mechanism force need be overcome nor

need any locking structure be displaced to remove the -data cartridge 15 from the tape drive assembly 10 as in prior art devices.

An alternate cartridge unlocking action is also possible with this tape drive .assanbly. Ηie cartridge 15 can be pushed forward toward tie limit stops 41, 42 as the outer end of the cartridge is lifted upward. The cartridge lifting action will pivot the cartridge cn the spring loaded bearing surfaces 44, 45 as illustrated in Fig. 6 and the forward edge 80 of the rectangular opening 22 of the cartridge baseplate 21 will clear the reference surface 38. The pushing action of spring 75 which normally keeps a driving force against the drive wheel (and auxiliary resilient means, if used, which normally keeps the cartridge in contact with reference surface 38) assists in ejecting the cartridge past reference surface 38 and out of the lodcing position where upon the cartridge can be easily withdrawn.

The drive motor 60 is preferably a servomotor controlled at a constant speed by a feedback circuit that monitors the rotational speed using encoder wheel 65 and a photoelectric sasing device 66.

Although the present invention has been described in detail, it can be appreciated that modifications and improvements within the spirit and scope of this invention may be made by those skilled in the art upon consideration of this disclosure.