US2983155A - Incremental drive - Google Patents

Description

May 9, 1961 J. P. NORTON EI'AL 2,933,155

INCREMENTAL DRIVE Original Filed Aug. 27, 1956 a heets-Sheet 1 WILLIAM F. DALEY,

JAMES P. NORTON,

INVENTORS AQENT.

May 9, 1961 Original Filed Aug. 27, 1956 J. P. NORTON El'AL INCREMENTAL DRIVE I mm Eig. 5

8 Sheets-Sheet 2 WILLIAM F. DALEY, JAMES P. NORTON,

(NVENTORS.

am/{M AGENT.

y 1951 J. P. NORTON EIAL 2,983,155

INCREMENTAL DRIVE 8 Sheets-Sheet 3 Original Filed Aug. 27, 1956 WILLIAM F. DALEY, JAMES P. NORTON,

Zak/{0% AGENT.

May 9, 1961 J. P. NORTON EI'AL 2,933,155

INCREMENTAL DRIVE Original Filed Aug. 27, 1956 8 Sheets-Sheet 4 WILLIAM F. DALEY,

Fi JAMES P. NORTON,

INVENTORS.

am/{M AGENT.

y 1961 J. P. NORTON l'AL 2,983,155

INCREMENTAL DRIVE 8 Sheets-Sheet 5 Original Filed Aug. 2'7, 1956 AGEN T.

y 1951 J. P. NORTON EIAL 2,983,155

INCREMENTAL DRIVE Original Filed Aug. 27, 1956 8 Sheets-Sheet 6 ST m Si no! I i a F j 0 I c PS ompuier /9() r 51' And a Dc) Conirol i l cx wesivsav.

i l I Conso fig. 5a..

WILLIAM F. DALEY, JAMES P. NORTON,

INVENTORS.

2., WJOM;

AGENT.

May 9, 1961 J. P. NORTON ETAL INCREMENTAL DRIVE Original Filed Aug. 27, 1956 8 Sheets-Sheet 7 Pin Reader Station To Power p y on Console] WlLLlAM F. DALEY,

JAMES P. NORTON,

INVENTORS.

3m Xi-JIM AGENT.

May 9, 1961 J. P NORTON ETAL 2,983,155

INCREMENTAL DRIVE 8 Sheets-Sheet 8 Original Filed A 27, 1956 WILLIAM F. DALEY,

E 1 g. 5C.- JAMES P. NORTON,

INVENTORS.

wowm AGENT.

INCREMENI'AL DRIVE James P. Norton and William F. Daley, Los Angeles, Calif., assignors to Hughes Aircraft Company, Culver City, Calif., a corporation of Delaware Original application Aug. 27, 1956, Ser. No. 606,354. ;)1ig'i3lgd and this application Feb. 27, 1958, Ser. No.

5 Claims. (Cl. 74-125) This invention relates generally to reversible incremental mechanical drives and is a division of a copending application of the applicants, Serial No. 606,354, filed August 27, 1956, entitled Perforated Tape Reader and assigned to the assignee of this invention.

For the purpose of demonstrating an application of the reversible incremental drive of this invention, the drive is illustrated herein as applied in an arrangement for reading perforated tape. This involves certain specific considerations which are only exemplary.

Commercial perforated record reading apparatus frequently involves a row of spring loaded pins operated in time sequence with the tape feeding and indexing mechanism which incrementally moves the tape in one direction. During each instant, when the tape is stopped by the feeding and indexing mechanism, the spring loaded reading pins are advanced into reading position with respect to the tape. In this position, certain of the pins may pass through perforations in the tape and certain other of the pins may engage the tape and be arrested in their movement with respect to the tape. Thus, the

' displacement of the pins is indicative of the presence or absence of perforations in the tape and in accordance with a suitable convention of binary code, the pin positions are indicative of a particular condition. Presently available commercial arrangements are capable of feeding the tape in one direction only. This is .satisfactory in many applications. However, in certain applications wherein speed of tape handling and accuracy in final results represents criteria which must be obtained, atrangements of this type are inadequate.

One such application is found in machine tool automation by digital means. In such applications, any error existing in the perforated code in the tape may result in a gross error in a machine or assembly operation performed by the automation system which may ruin the United States Patent 0 set up so that the code depends upon odd numbers of holes appearing in any single row of perforations in the tape. Thus, a mistake of one hole or perforation in the tape, termed a parity error, which is a common variety of error, would result in the appearance of an even number of holes in any single row. The equipment receiving the information from the position of the pins may thus be organized to reject any code involving an even number of tape perforations. Also, even though an odd number of perforations may exist, it is conceivable that relays or other switching devices responsive to pin positions may operate improperly which would also produce an indication of a parity error. In either event, it is desirable at this point to bring the operation to a stop, reverse the tape to a predetermined point beyond the seeming error in the tape and thereafter reread the tape a second time to check the condition. Occurrence of the error a second time may. then be utilized to completely stop the operation to determine the source of the error.

To accomplish this, provision must be made to reverse the feeding and indexing mechanism and at the same time to reverse one or both of the motor drives for the reels to effect tape reversal. Thereafter, the reverse feed must be stopped and the reader started up in the forward direction which requires restoring the operation of the tape feeding and indexing mechanism together with the reel drives to their original conditions in which the tape is fed in a forward direction for reading.

It will be seen from the foregoing discussions that the requirements of a reversible incremental drive in a perforated tape handling application are stringent. The drive must be positive in its operation and must be precise in indexing. Otherwise the tape may not be properly fed or the tape may be indexed in a position which is not in precise coincidence with the position of the reader pins. In either situation, faulty operation may result.

Accordingly, one object of this invention is to provide a reversible incremental mechanical drive which is simple with respect to operational requirements and Which is positive in operation.

Another object of this invention is to provide a reversible incremental mechanical drive with provisions for at the point wherea seeming error exists, so that in the event the error was the result of malfunction of some .part of the system and not of the code the operation may be continued, assuming of course that the machine malfunction did not occur a second time.

Frequently, perforated tape readers are provided with be controlled so that the tape is fed into, the reader and,

wound up at the exit side of the reader in such fa way as to minimize tape tension betweenaeither offthe reels and the feeding and indexing statior'r i-n therea'derg j The 'checking'of tape errors requiresthat the re er andthe reels be reversible in operation. Byway of xpla tion) of the natureof such an errorythe arrangement-,"maybe 1 various aims and objects of this invention.

-ent operating position;

jdifferent operating position; l tionship off the circuits-of completely disengaging the driven member from the incremental drive.

A further object of this invention is to provide a reversible incremental drive of the character referred to which provides positive incremental displacement and indexing of the driven member.

Still another object of this invention is to provide a reversible incremental-mechanical drive in which reversing of the drive connections takes place only when the drive is disconnected from the driven member.

The foregoing-statements are merely illustrative of the Other objects and advantages will become apparent from a study of the following specification when considered in conjunction withthe accompanying drawings, inwhich:

Fig. 1 is a perspective view'of a perforated tape handling apparaus embodying the reversible incremental drive of this invention; I

Fig. 2 is an elevational view fragmentarily in section illustrating certain mechanical details of the reversible incrementalxdrive in one operating position;

Fig; 3 is a sectional view taken on the line 3'-3 of Fig. 2; v

Fig. 4 illustrates the mechanism ofFig. 2 in a differ- .qFig. 5 illustrates the mechanism of Fig: if in a still drillustrates th 6a, 6band..6c .and

' ape-n r151 theihole in the tapeiu dicatingthesta eral organization of the main components of the tape handling apparatus/ The arrangement illustrated comprises a tape readergene'rally designated 1, disposed substantially centrally on the upper side of housing 2. Reels '3 and 4 are rotatably mounted at opposite ends of the tape re aderl, reel 3 being the supply wheel and reel 4 being the take-up reel. The tape is fed normally in a forward direction from the supply reel 3 through the perforated tape reader 1 and thereafter is wound up on the take-up reel 4. The reels 3 and 4 are powered by respective eelctric motors 5 and 6. These motors appear only in the wiring diagram in Figs. 6a, 6b and 6c for this system and are not shown at this point. in the interest of simplicity. Each of motors 5 and 6 is arranged in a suitable electrical control circuit yet to be described adapted to be controlled in part by respective tape tension arms 7 and 8.-which are suitably pivotably mounted so that the tape engaging portions are gravity biased or spring loaded, if required, into engagement with the paper tape. The purpose of these arms is to provide suitable control over the respective reel motors 5 and 6 so that the tape is never tensioned asa result of improper supply, or take-up of the tape which hasbeen read.

Movement of the tape through the tape reader 1 is controlled by a feeding and indexing mechanism which drives a sprocket wheel generally designated 10 having a plurality of circumferentially spaced sprocket teeth 11 which engage correspondingly spaced holes arranged in a line substantially centrally along the paper tape.

ternall-y of the housing 13 which encloses the tape reader mechanism. A thumb wheel 14 is mounted on the end neath a slotted guide 16 having an arcuate shaped portion, positioned overportions of the sprocket wheel on opposite sides of the sprocket teeth 11, which maintains thetape in positive engagement with the sprocket teeth.

The sprocket wheel 10 is mounted on a shaft 12 extending ex- The tape continues across the top of housing 13 extending through a third guide '17, passing from guide 17 beneath tensionarm 8 and thereafter being wound upon the take-up reel 4.

:JTQYiIlgQ; single projection 31 controlling a drive link assembly generally designated 32. This drive link assem- A contact roller 18 mounted on a control arm '19 is operable between a position in which it rotatably rides an edge of the tape and a second position in which it disengages the tape. As will be explained hereinafterjn connection with Figs. 6a, 6b and 60, this roller and its contact plate 17a constitute a stop switch SS in an elec- V trical circuit which is completed through suitably posi .from left to right as viewed in Fig. 1, suitable means are provided such as a stop switch 'magnet'SSM, to lift roll during a message rewind operation, roll 18 is moved into a position engaging the tape. The holes which are detected by the contactroll 18 are positioned on the tape 7 margin atthe beginning of a message indicating the start 4 a tric circuit which operates to stop the rewind operation at this point.

For a total rewind operation when the tape is to be removed and replaced by another tape, the control afforded by the contact roller 18 is eliminated, and the tape is totally rewound onto supply reel 3 so that it may be completely removed andreplaced by a reel having a different code.

The mechanical arrangements whereby the various op erations referred to above and others may be accomplished appear in Figs. 2 and 3 which illustrate the components of the mechanical assembly in one operational position, Figs.'4 and 5 indicating other operational posispeed. Motor 20 drives a pulley21kwhich is belt-connected to a pulley 22, connected'by means of a springload ed friction clutch, not shown, to a shaft 23 which constitutes the input shaft to the reader. Thus, at any time when the shaft 23 is secured against rotation, pulley 22 rotates with respect to the shaft and whenever the shaft is released the friction forces are sufficient to afford a positive drive of the shaft for the torque loading imposed thereon by the feeding and pin reading mechanisms. Rotation of the shaft 23 is controlled by aconventional type of single revolutional clutch, generally designated 24, herein referred to as the reader clutch, which is provided with a peripheral projection or stop 25 adapted to be engaged by a spring loaded latch 26. This latch may .be operated in any suitable manner. The control herein "indicated involves an electromagnet 27 disposed influx linking relationship with latch 26 so that upon energization of the reader clutch coil RCC the latch may be withdrawn from the position indicated engaging stop 25 to release the clutch.. For the purposes of this invention, coil RCC may be maintained constantly energized excepting during initiation of reversing operationof the tape sprocket wheel mat-which time the electrom'agnet f27,'as' will be described hereinafter, is de-ener'gized .to permit engagement of the latch 26 with stop 25. Although not herein illustrated, latch 26 may be additionally actuated by means of a cam driven by the shaft 23 controlling a 'suitablelever whichengages and moves latch 26 in a direction to engage the clutch surface. These and other equally obvious expedients will be apparent to those skilled in the art. j r

Shaft 23 is connected to anddrives a feed cam 30 bly incrementally rotates a ratchet wheel .33 which is "secured to drive :the shaft 12 vwhich mounts the' tape "sprocket wheel 10. rotates in one direction,'as indicated by the .the cam 30 in Fig. '2. V C Drive link assemblyr32 comprises a pair of pivotally (See.Fig., 3.) Shaft 23 always mounted, parallel connected, cam actuated levers 34 and 1 8 oft the tape to minimize frictional drag. However,

of the code; Thus, during rewind of the particular m'es- .1

' a sage; the contact" roller is separated from the bottom sec- 7 tiou 17a ,of guide 17, which functionsi'as" the. stationary TpOrtionbf theElctriCaI contact arrangement '88, so'that" the-circuitgcontrolled by the} c"ntact rollerdsfmaintainedI rt' of the' ,35 respectively. Lever 34, is pivotally mounted about a stationary stub shaft 36 and lever 35 is pivotally mounted about a stationary stub shaft '37. Lever.34 is provided with a cam follower roller 38 which rides the; surface of Thus, the lever 34 is moved between the position indiicated and a counter-clockwise position as'seen in Fig. 4 wherein the roller 38 rides against. the circular-portion of c a1 n', 30. v,Movement'of lever;3i4 is-imparted to lever 35 TbymmQaDSiQf a link -4ft pivotallyconnected between the 'links'3 lzand"35.' lfihus, as the: cam roller. is displaced by jrota'tion of the cam"30, 'both jof the 'links. 34'fa're moved betweenQtheiposition shown TFigf 1am; a counter- 'se, p ositioni sliowniin Fig. 4.

arrow adjacent A tensionspring 39 connected to lever 34 7 applies a counter-clockwise bias theretov suflicient to maintain roller 38 in'contact with the surface of cam.3ii.

The free ends of levers 34 and 35 pivotally mount respective drive links 41 and 42, the free extremities of which carry respective drive pins 43 and 44. These free extremities are disposed on opposite sides of the ratchet wheel 33 and are controlled to selectively engage the ratchet wheel by means of a shift arm 45. Shift arm 45 is pivotally mounted by pin 46 between spaced side portions 47 and 43 of a vertical support 50 having a horizontal base portion 51 which is bolted by means of bolts 52, to the upper edge of a plate 53 constituting the main mounting or support plate of the reader mechanism. Shift arm 45 is provided with a horizontal projection 54 as seen in Fi 2. A clamp 56 at the top of vertical support 50 receives a reduced diameter tubular projection 57 of the housing of a reverse feed solenoid 58 having a plunger 6%, the end of which engages the end of projection 54 on the shift arm. A compression spring 59 disposed between the support 50 and the shift arm, torques the shift arm in a counter-clockwisedirection to the position shown in Fig. 2 when the solenoid is de-energized.

Drive links 41 and 42 are biased towards each other by means of a tension spring 61 which is tensioned between pins 62 and 63 secured in the respective drive links at points intermediate their respective points of pivoting and their free extremities, and in a position affording clearance between the tension spring 61 and the ratchet wheel 33, so that the tension spring will not interfere with ratchet wheel movement. Shift arm 45 is provided with a cam-shaped lower extremity 64 which'is disposed between lateral extensions of the respective drive pins 43 and 4 (see Fig. 3). As will'be seen in Fig. 3, the shift arm extends downwardly beside the surface of support plate 53 and is provided with a suitable slot 65 which clears the shaft 12 in each of the two positions occupied by the shift arm. For either position of the shift arm 45, either the forward or the reverse drive link rides against the surface of the cam-shaped portion 64 of the shift arm. Thus, as seen in Fig. 2, the drive pin 44 of the reverse drive link 42 rides against cam edge 66 and is thus prevented from engaging notches in the ratchet wheel 33. On the other hand, cam edge 67 is'displaced from the path of movement of drive pin 43 of forward drive link 41 and, as a consequence, is not engaged by drive pin 43. Drive pin 43 may thus on its upward movement engage a notch in the ratchet wheel and drive the ratchet wheel a distance corresponding to the pitch of one tooth. I

Fig. 5 illustrates the mechanism arranged for reverse drive of the ratchet wheel. For this condition, the solenoid 58 is energized which drives. the plunger 69 of the solenoid to the right frornthe position shown in Fig. 3 to apositiondetermined by the limits of the solenoid travel. Thus, the shift arm is rotatedin a clockwise direction to the position indicated. The edge 67 of the shift arm cam 64 now engages drive pin 43 of forward drive link 41 rotating this drive link counter-clockwise to a position in which the drive pin 43 no longer engages the teeth of ratchet wheel 33. In this position cam edge 66 is sufficiently displaced that drive pin 44 of reverse drive link 42 may now engage the teeth of ratchet wheel 33. Thus, as the drive linh assembly 32 rotates'under the control of feed cam 39, ratchetwheel 33'is rotated in a counter-clockwise direction to feed the tape in a reverse tion' by forwardjrive link 41 the ldrive link 41 whenretracted is displaced fromtlie ratchet wheeli by a stationary pin 68 which-is securedm support 53.: Pin .68 engages an offset edge 70on the forward driv'e link'whic h camsthe drive link 41 in acounte'r-clockwise direction-as the link is retracted to positively disengage drive pin 43 from the teeth of ratchet wheel 33 towards the lower end of the retraction stroke. A similar stationary pin 71 cooperates with an offset edge 72 on reverse drive link 42 to correspondingly control the reverse drive link when the shift arm is in the reverse drive position. This has not been illustrated herein but is readily construable from the operation illustrated and described in connection with the forward drive link 41.

Ratchet wheel 33 is positively indexed in each incremental angular position by means of an indexing arm 73 which is pivotally mounted on support 53. This pivotal mounting comprises an eccentric pin 74, adjustment of which shifts the pivot axis of the indexing arm 73 between positions to the left and tothe right of that indicated for the purpose of positively indexing the ratchet wheel in such a position that the reading pins may be indexed with the perforated code of the tape whenever the ratchet wheel is indexed. Positive indexing of the ratchet wheel is obtained by means of a roller 75 rotatably mounted on the free end of indexing arm 75. This arm is spring loaded to detent position by means of a tension spring 76 connected between the other end of the indexing arm 73 and a pin 77 secured in support 53. Provision is made herein for physically displacing the index arm 73 in a counter-clockwise direction to disengage the detent roller 75 from the ratchet wheel 33 so that the ratchet wheel 33 may be free to rotate without the indexing forces acting thereon. This is accomplished by means of a substantially L-shaped arm 78 which is pivotally mounted about the pin 74. This L-shaped arm is provided with an'oifset section functioning as a shoulder 80 disposed to engage an adjacent edge of the indexing arm 73. The left-hand extremity of the L-shaped arm 78, as viewed, functions eifectively as an armature being provided'with a pole member 81 confronting a pole 82 of a solenoid or electromagnet 83. Thus, energization of this electromagnet is effective to supply sufiicient force to the extremity of the L-shaped arm 78 to overcome the spring loading of the indexing arm 73 provided by spring 76, to rotate the indexing arm in a counter-clockwise direction to disengage the detent roller 75 from the ratchet wheel 33.

The reading pin station is schematically illustrated'at 86. This reading pin assembly is controlled by a cam 87 which is driven by shaft 23. A cam roller 88 is arranged in a suitable linkage 9Q, illustrated only in schematic form in the interest of simplicity. Linkage 99 is conventionally connected to the reading pin assembly to move the reading pins to and from tape reading positions. Cam 87 is indexed with respect to feed cam 30 so that the reading pin assembly is displaced from tape reading position and positively maintained out-of-tape reading position and throughout that interval in which the linkage assembly 32 incrementally moves the ratchet wheel 33 to displace the tape during the tape feeding operation. Whenever the tape feed'cycle is completed and the tape is locked against further movement by the detent roller 75, continued rotation of shaft 23 inthe' direction indicated, rotates cam 37 so that roller 88 moves overa lower edge 'of the cam 87. This physical displacement'of roller 88 and the linkage 90 associated therewith displaces the reading pin assembly 86 moves the reading pins into tape reading position.

Ina practical embodiment of this invention, the axial position of the reading-pins, as determined by the presence or absence of perforations in the tape, are utilized to con trol suitable switching means betweenopen and closed positions whereby an electrical indication of the axial". position of the pins is obtained. Arrangements for de- :tecting the positions of the pins havenot' been -illus;-

trated hereininthe interest of simplicity.

pi'ovides' three. main modes of operation addition forwardreading and some ancillary operations,

' hereinabovd presence of suitable control of electromagnetic devices 27,- 58 and 83. These three modes are as follows:

(1) Message rewind.In the message rewind mode of operation, the tape isrewound from the end of the message to the start of the message which provides complete rewinding of the message which has just been read from the tape. To accomplish this, electromagnet 27 is deenergized, which drops the latch 26 against the surface of the single revolution clutch 24. Thus, as the projection 25 moves counter-clockwise, it is engaged by the latch 26 which stops further rotation of shaft 23 and locks cam 30 in a position such as illustratedin Fig.

4. Energization of the electromagnet 83 rotates theindexing arm 73 counter-clockwise to disengage the detent roller 75 from the ratchet wheel. Thus, the ratchet wheel is released so that it may rotate freely during the message rewind operation. At the same time, and referring to Fig. l, provision is made through the electrical circuits yet to be described to reverse the energizing connections for the respective reel motors so that the reel motors drive the reels in reverse directions. The control of the supply reel motor is such during the rewind operation that this motor is started up under the influence of reduced energization which takes up the slack in the loop of tape adjacent the supply reel and displaces the tension arm 7 upwardly as viewed. During this interval the light tension applied to thetape by tension arm 7 accelerates the tape sprocket wheel 10 which is now freely rotatable and the tape begins to move in the reversedirection through the reader. As the slack is taken up in the tape loop adjacent the take-up reel 4, tension arm 8 associated therewith also moves upwardly as viewed. As the tape speed increases through the tape reader and the respective tension arms move upwardly, indicating that most of the slack is out of the tape, suitable connections are made to increase the energization-of the supply reel motor at which time the reel speeds increase and the tape is wound at high speed on the supply reel.3. In this mode of operation, control arm 19 is displaced to engage contact roller 18 of'stop switch SS with the tape. When the perforation in the tape indicating the start of the message moves beneath contact roller 18, the electric circuit between contact roller 18 and stationary contact plate 17a is completed. This circuit is arranged to de-energize both reel motors and at the. same time to control the application of reel brakes. (not shown in detail) to stop therespective reels.

(2) Total rewind.ln the total rewind mode of operation, the reader drive mechanism is positioned as described in connection with the message rewind mode of operation. This operation is essentially the same as that described for message rewind excepting that provision is made to prevent the contact roller 18 from stopping the reel motors at the start of any particular code or message onthe tape. This may beaccomplished through other switching arrangements in the circuit including the contact roller 18 or, alternatively, may be accomplished by keeping the contact roller out of physical contact with the tape. The total rewind operation maybe initiated and stopped by suitable manual switching means.

(3) Reverse reading-4h the reverse reading mode of separation, the incremental feed mechanism is switched of the code or message and again whenever cam roller 38 rides over the lower part of cam 30, solenoid 58 is de-energized to shift the drive mechanism to its forward drive position. The tape is now again moved incrementally in a forward direction through the tape reading station. If the parity error does not occur on this second pass of the tape through this pin reading station, the operation continues. If, however, a parity error is again indicated, arrangements are provided to stop the operation at that point.

The circuit arrangement illustrated in Fig. 6a through 60 provides the control sequence 'of the electromagnetic devices 27, 58 and 83 to achieve the functional control- -of the system as hereinabove outlined.

In the circuit as shown, all relays are in their deenergized condition. The tape is assumed to be threaded through the reader with sufficiently large tape loops between the vreader and the respective reels that the tension arms 7 and 8, respectively, are in their lower positions.

The tape reader feedmotor 20 is assumed to be running.

' This motor, being uncontrolled by the circuit, is not illustrated therein. In this circuit condition, the coil of the clutch electromagnet 27 which controls rotation of the reader drive shaft 23 is de-energized and'latch 26 is engaged with projection 25 on the rotary portion of the clutch. Thus, shaft 23 is stationary. Similarly reel drive motors 5 and 6 are de-energized.

7 Normal forward reading 0perati0n.To startthe tape, the switch PS in the D.C. power supply at the console is closed which applies direct current to the system over the positive and negative power. supply conductors P and N, respectively. To start the tape in the forward direction the reader clutch must be energized. The circuit for reader clutch 27 across the power supply conductors includes, normally open contacts F2a, normally open contacts, Zla, normally open contacts 83a normally closed over-load tape tension contacts OLCl, the coil RCC of reader clutch 27, and ,normally open contacts from forward to reverse operation and the tape is driven 7' incrementally in a reverse direction by means'of the tape sprocket wheel 10. Thus, in this modeof operation which "is initiated by a parity error in the tape as earlier de-.

, scribedhereimthe reader clutch coil is, file-energized permitting latch26to engage'stop 25'tostop shaft 23 with the drive 'links retracted. "Solenoid 58 is energized to irms the shift arm 45 to its reverse drive position. Energization ofthis solenoid takes place only whenever the;

cam roller 38 rides onfthe lower part of the feed ca m 3t),

STla of the start tape relay ST. Manually operated switch S is now moved fromits off position indicated to its on position. This opens a contactSlb in the circuit forthe coil of rewind relayR, opening D.C. power contacts 82b, closing D.C. power contacts 82a and closing contacts 83a in the reader clutch coil circuit. The application of D.C. power to the sys tem through closing of the power switchPS energizes forward relay F, in a circuit across the positive and negative powersupply conductors including the normally closed contacts Ylb of relay Y, the coil of relay F and normally closed contacts Ylb of relay Y, thecoil ofv relay F and normally closed contactsRlb of rewind relay R; Contacts F2a inthe reader clutch coil circuit'now close, Relay Z is energized in a circuit including the coil of relay .Z, the normally closed contacts 'Plb of parityrelay PA and contacts 313121 of relay, 3d. ReIaysZD. and 313 are presentlyyenergized since contacts X31; of relay X are closed, relay X- presently being de-energized; Conin'which position thedrive links are completely -retracted,

as stated and disengaged from. the ratchet wheel 33.. Thisfi ndi h in the; re i ssme e tac ts ZIa in .the-clutch coilcircuit now close. This cornpletes the reader clutch coil circuit :except for closing of contacts STla of start,-,tape relay ST.

'In'thismode of operation the reversing solenoid 53 is .de-energized s'ince contactsfXZkgof relayX, the only..con-, tacts which control it, are OPtEflififIfhUQlll shift arm'45' is positioned to permit engagement of forward drive link 41.;with ther ch tzwhe ffi 1-.

The circuit for controlling supply reel motor for forward tape feed includes the normally open contacts 52:: of manually operated switch S, which switch is now closed, the normally closed contacts M4b of relay M, this relay being deenergized in this mode of operation, the reel jogging contacts RI, resistor R3, resistor R11 which provides slow speed operation of the supply reel motor when shunting contacts 1D1a are open, calibrating resistor R10, normally closed contacts Mlb, the armature of supply reel motor 5 and normally closed contacts M21). In the forward mode of operation, contacts R3 control the euergization of the supply reel motor and close when the tape loop diminishes sufficiently to raise the tension arm 7 the required amount to close contacts R]. Motor field 5F is energized in shunt relation with the supply reel motor armature.

' The circuit controlling take-up reel motor 6 to wind tape passing through the reader includes the now closed contacts 82a of the main switch, normally closed contacts M4b of relay M, normally closed contacts Xob, normally closed contacts WCZ, which are controlled by tension arm '8 at the take-mp reel, half of the take-up reel motor field 6? and the take-up reel motor armature. Contacts WCZ under the control of tension arm 8 close when the tape loop increases sufficiently. This energizes the motor to take up the slack in the tape. When the loop in the tape at the take-up reel diminishes sufficiently tension arm 8 opens contacts VVCZ to tie-energize the take-up reel motor 6.

In this mode of operation, the supply reel brake coil SR3 is not operated because the motor is operating at relatively low speed and appreciable overrun does not occur. However, the take-up reel brake coil TRB is controlled in a circuit including normally closed contacts M3b, normally closed contacts X4b, contacts WCl operated by tension arm 8, isolating rectifier CR2 and the coil TRB of the brake. This brake, not shown in detail in the interest of simplicity, is spring released and electromagnetically applied. it may be any suitable type of commercially available friction brake. Contacts W01 are controlled by tension arm 8 to close and energize brake coil TRB to apply the brake each time the tension arm 8 lifts su ficiently to close the contacts WCI. This movement as previously explained opens contacts WCZ which (lo-energizes the take-up reelmotor circuit.

As stated hereinabove, energization of start tape relay ST close contacts 3T1, completing the final contact link in the circuit 'ror coil RC of reader clutch 27. Energize.- tion of reader clutch coil RCC magnetically moves latch away from the surface of the rotary portion of the clutch, disengaging the latch with stop 25, permitting the reader shaft 23 to rotate to incrementally drive the tape sprocket whcelthrough ratchet Wheel 33 andthe drive fed through a suitable computer and control arrangement I )0 indicated only in block form to the-coil of relay ST;

Such expedients are disclosed only me. generalway herein'since, per se, they form no part of this invention.

Reverse reading.-Provisi o'n is made for checing a common variety of error occurring in preparing the tape wh ch is to be used. Usually a special type of tape punch is used to perforate the tape. This'punch may; be automatically controlled fiom' a keyboard. In'thi operation, it is not uncommon topunch-onehoIe'more-or less in a particular row. This type of error can be detected with-a minimum of equipment if the code parity is based -on an even or odd number of holes in each row of perforation. If an odd parity is chosen, for example, the computer and control may be arranged to reject an even number of holes. Since this sort of error may also result from momentary malfunction of electrical components, such as relays, it is desirable to recheck the tape at the point the seeming parity error occurred. A second parity error occurrence may then be regarded as significant of a tape error or, if not a tape error on inspection, an electrical failure requiring correction. As a practical matter, it may not be feasible to express all the information in a code having an odd number of holes, in which case a separate tape column termed the parity column may be used to insert a parity hole to make an odd number of holes in a given row, the computer discriminating the parity hole from the code.

The mode of operation to be described in actually a reverse reading operation in which the tape movement is reversed by the drive, with incremental indexing in the reverse direction as in the forward direction. The reading pins operate as in the forward direction to engage the tape during reverse feed. This reverse feed may be stopped at any point'beyond the error by a suitable counting arrangement or the like. In one practical embodiment of this invention, however, it Was found desirable to utilize a separate tape column having a single hole at the start of the code. In the forward direction of operation, this hole, indicative of start of code, signal the computer and control 94 that the coded message is about to begin. In the reverse mode of operation, this may be utilized again as an indication of the start of code but at this time to stop the reverse feed of the tape when it is engaged by the start-of-code reading pin. The signal received from the start-of-code pin stops the tape and initiates the shifting cycle to again move the tape in the forward reading direction.

In the system the occurrence of a parity error whether in the tape or through computer and control malfunction results in energization of reverse tape relay RT which closes its contacts RTla and energizes the coil of parity relay PA. Contacts Plb now open and momentarily deenergize relay Z, the circuit for which also includes contacts 3D1a of relay 3D, which is now energized, and tape feed contacts TF. When relay Z is de-energized, its 'contacts Zita in the circuit for the reader clutch co'il RCC open and latch 25 engages projection 25 stopping rotation of reader drive shaft 23. Contacts Pla of the parity relay now close. These are the only contacts in the coil a circuit of relay X. Contacts Xla close after a delay determined by the time constant of the coil circuit including resistor R14 and capacitor C15 which latter shunts the coil of relay X. Contacts Xla energize relay C. Con tacts C111 shunt the contacts P1b, wh ich are now open, in the circuit for the coil of relay Z. However, relay C is time delayed by an RC circuit, including a series resistor R13 and a shunt connected capacitor C3 Which delay the pick-up of relay C and consequently delay closing of contacts Cla. The time delay on relay C is about the same but prior to closing of contacts C1a,'which closes contacts 2131b. Closure of contacts X3a shorts the capacitor C7 shunting the coil of relay 3D through a rectifier CR4 which promptiy tie-energizes the coil., Contacts 3Dia open immediately. Thus, when contacts C14 close the 'coilof relay Z is' energized to again. close the circuit for" the reader clutch coil RCC.

The coil of solenoid '58 is controlled only by contacts X211 of relay X which is not energized. j Relay X time do- 'lays 'energization of shift'arin 4:7 sufiiciently to permit the reader clutch to stop shaft 23.. "Thus, after stopping of.

thereader driveshaft 23, as described, contacts X2a energize the coil of solenoid 58 to 'reverse the shift arm position, shifting the drive linkage .32' for reverse feed :of the. V tape. Mornentariiy, thereafter, .rel-ay Z. is energized by 1 bly 86 detects the start of code hole in the tape.

' circuit tone-energize the reader clutch coilRC. I Thus, the readen drivelshaft; 23 is stopped; Whenrelayr-F is closing of'contacts Cla and Dlb and the reverse fee operation of the tape begins.

' This operation continues, for example, until the startof-code reader pin' (not shown) in the pin reader assem- At this point, the signal current to the coil of reverse tape relay RT is cut OE and relay RT is de-energized, opening its contacts RTla and die-energizing parity relay P. Opening of contacts Pla opens the circuit for the coil of relay X. However, this relay is delayed on drop-out by the charge on the capacitor C15 connected in shunt with the coil thereof. Contacts Plb close in'the circuit for the relay Z. When relay X drops out contacts X3b close. Relay 2D now picks up quickly opening contacts 2D1b. and de-energizing relay Z which opens the reader clutch circuit and stops the reader. Contacts XZa open and solenoid 58 is de-energized which shifts the shift arm 45 to the forward drive position. After a time delay determined by resistor R5 and shunt capacitor C7, relay 3D picks up and contacts 3D1a close, energizing the coil RCC of the readerclutch and the incremental drive in the forward direction begins.

If the parity error does not occur the second time, tape reading in the forward direction continues normally. If the parity error occurs a second time, the computer and control then operates to de-energize stop tape relay ST to stop thereader completely.

This function takes place within the computer and control and interrupts the signal supplied to the start tape relay ST, which opens the contacts STla in the circuit for reader clutch coil RCC which stops rotation of reader drive shaft 23. 7

During this operation, since' only a relatively small amount of'tape is fed in the reverse direction, it is unnecessary to reverse the supply reel motor. However, the take-up reel motor is reversed by contacts of the X relay. It will be recalled that during the wind-up operation of the take-up reel, the take-up reel motor was controlled through contacts X61: and the tension arm. operated contacts WCZ, which were normally closed and which open whenever the tape loop diminishes. When relay X is energized, contacts X61) open and contacts XSa close which .shifts the energization from one extremity of the split field'winding SE to the other through the contacts UWC2 operated by the tension arm 8. These contacts are closed when the tape loop is small and open when the tape is loose and thus operate to control the reverse rotation of'the take-up reel to maintain a tape loop during the reverse reading operation. 1

'Message rewind.--Whenever the message on the tape for a particular operation has been completely read, suit-' able coding in the tape may be provided to indicate the end of the message. This end of the message code is detected by the reader pin station which applies an end of the message signal tothe computer and control system. J

-The computer and control system now operates to energize the'coil of rewind relay RWT andthisoperation continues until'the, message is completely rewound so that the message may be reread through the reader.

Energization of relay RWT closes contact RWT a in th until rewind is completed. Closure of contacts Dlaof is energized, its contacts Ylb in the coil circuit for relay F open and its contacts Yla in the circuit for the coil of relay M close. This circuit is completed through the contacts Alb of the relay A. This relay is presently deenergized. Contacts Mla and M2a reverse the armature connections of the supply reel motor 5. Contacts M411 now open and disconnect the control for the take-up reel motor'and contacts M4a close to complete the energizing connection for the supply reel motor through the contacts 52a of the main switch S. Energization of the supply reel motor is now controlled through a resistor R911 in series with a resistor R9. The voltage drop across resistor R911 results in the application of a lowered armature voltage to the supply reel motor armature and this motor operates at a predetermined low speed, taking up the slack in the tape adjacent the supply reel and gradually increasing the speed of the tape sprocket wheel 10 which is now released for free rotation due to energization of the detent solenoid. Since the supply reel brake is maintained de-energized in this mode of operation, it occupies its spring released position. j

Closing of contacts M4a also complete an energization circuit for reversing the take-up reel so that it rotates in a direction to unwind the tape. This circuit extends through the contacts X5b of the presently de-energized relay X, through the contacts UWC2 operated'by tension arm 8 and through the split motor field and armature in series in such a way as to run the take-up reel motor 6 in adirection to unwind the tape. Contacts UWC2 are closed when the loop in the tape adjacent the supply reel diminishes a certain amount to close the motor circuit to unwind more tape and open asthe loop increases.

Thus, the motor is intermittently energized depending upon the requirement for the supply of tape.

Contacts M3a which are now closed, in conjunction with contacts UWCl also operated by tension arm 8, complete the circuit for the take-up reel brake coil TRB. Contacts UWCl open and close in reverse order with respect to contact UWC2. Thus, when the motor TRM is de-energized, coil TRB is energized to set the brake and when the motor TRM is energized the brake coil TRB is 'de-energized. Since the supply reel is powered to drag the tape through the reader, it is unnecessary to actuate the shift arm to reverse the sprocket wheel drive linkage. This mechanism is in its retracted position with roller 38 riding on the low part of feed cam 30 and roller 88 riding on the high part of cam 87 which retracts the reading pin assembly 86 from tape reading position.

As pointed out hereinbefore, roller contact 18 of stop switch SS is utilized to detect the beginning of the message.

V This is done by moving roller 18 into a position riding along the edge of the tape, a suitable .hole inthe tape 'plete a control circuit for rstopping the rewind operation coil circuit for relay R. This opens contacts Rlb and closes contacts 'Rla. COntactsRIb de=ene rgize relay F which promptly openscontacts PM in the clutchreader die-energized, its contacts F15 close. This completes an energizing circuit for the coil of brake JrelayB which includes'contacts F111 and the now closed contacts R1a at the beginning of the message To this end, contacts B317 which normally energize the coil SSM of solenoid .83 controlling the position of contact roller 18 are open,

it being recalled that relay B is presently energized through contacts Flb and RM. Thus the solenoid is de- :energized and'the contact roller engages the papertape.

v 1 The rewind speed is increased 'by shunting the resistor 'Rll through closing of the contacts lDla. This is accomplished-by energizing the coil of relay ID by meansof a delay switch DEL which is controlled by tension arm .7.

- .Delay switch DEL is open whenthe tension'arm is down Con-jg. V, v v.

' celerating the tape sprocket wheel. Once the sprocket,

and is closed when the tension is raised afpredetermined amount. Thus, as-the loop adjacentthe supply .wheel is taken up during the message rewind 'operation,

the reel is operated at: low speed andlmeanwhile. is acwheel ismoving, the supply reel motor may be accelerated in therewind direction. Closing of contacts :DEL

13 this condition completes the energizing circuit for the coil of relay 1D. This relay is delayed in pick-up by' an RC circuit including series resistor R12 and capacitor C8 which shunts the coil. This adds a little time to the operation in thelow speed range to permit further acceleration of the tape and the tape sprocket wheel.

When the beginning of the message is reached, the roller contact circuit closes and completes an energizing circuit for the coil of relay A; Relay A upon energization opens its contacts Alb in the coil circuit of relay M, deenergizing this relay which switches the polarity of the supply reel motor armature circuit throughciosing of contacts M112 and M217. At the same time, contacts M4a open in the motor circuit to de-energize the supply reel motor. Since relay B is yet energized, contacts 32a remain closed so that upon closing of contacts M3!) the supply reel brake coil SRB is energized to set the brake. When contacts M4a open, the energizing circuit for the takeup reel motor is interrupted and the take-up reel brake coil TRB is energized in parallel with the supply reel brake coil SRB through a circuit including contacts M35 and BZa and extending through an isolating rectifier CR1 to the coil TRB of the take-up reel brake.

The de-energization of relay M results in opening of contacts Mfia in the circuit maintaining the coil of relay B energized and which includes the contacts Y2a of the relay Y which is yet energized. De-energization of relay B results in opening of its contacts Bla in the coil circuit of the detent relay D. Thereafter, contacts Dla of the detent relay open, de-ener-gizing the coil of relay Y. De-energization of relay Y results in opening of contacts Ylzz in the coil circuit of relay M and closing of contacts Ylb in the circuit for coil of relay F. The control of the rewind tape relay RWT need only be momentary, that is, sufiiciently long to allow'contacts M6a and YZa in the holding circuit for the coil of relay B to close. Thereafter, the relay R may be de-ener-gized which again closes contacts R112; Thus, when contacts Ylb close, the relay F is energized again to maintain contacts Flb open in the coil circuit of relay B. Energization of the relay F closes contacts PM in the reader clutch coil circuit. However, this circuit is open at contact STla at this time. Thus, the rewind operation is brought to a stop and the circuits are reset for the next forward reading operation of the message. For the arrangement described, this may be accomplished through either manual or automatic energization of thecoil of the start tape relay ST.

Total rewind-In an automatic machine tool control system, if it is desired to machine a different part a new tape is required. The present tape .is removed from the reader in a total rewind operation which is manually initiated. To accomplishthis, tape feed switch FF is opened and the main switch S is moved to position. This closes contacts Slb in a circuit shunting the rewind tape relay contacts RWT 1. This shunt circuit also includes in series the contacts TW3a of a total wind relay TW. Relay TW is energized by manual closing of rewind contacts RW. This closes contacts TW3a and com pletes the energizing circuit for the coil of rewind relay R. At the same time, normally open contacts TW2a of relay TW are'closed which energizes the coil SSM of the stop switch magnet. Thus,roller contact 18 is held away from the tape and its operation is eliminated. Contacts TWla complete the circuit from the direct current supply through the contacts S2b to the contacts M4a' which are now closed. The circuit for energizing the supply reel motor in the reverse direction is now completed through contacts lDla, M2a and Mia. Relay M is energized in this mode of operation by reason of the operation of relays B, D and Y as previously described, the latter of which, through closing of contacts Yla, energizes the coil of relay M. i

and M4a and thereafter continues through contacts X511 and UWCZ through half of the field winding 65 and the motor armature to the negative side of the line. When the tape is tight, contacts UWC2 remain closed so that the take-up reel motor remains energized. Since contacts M3a are closed, contacts UWCl energize the take-up reel brake, whenever the tape is loose, to set the brake and prevent excessive overrun. When the tape is completely rewound, the rewind switch RW is opened which stops the rewind operation.

if it is desired to read back a particular block of code which has passed through the reader, this may be accomplished by depressing and closing a push button BR. The operation which results from closing of contacts BR is similar to that which is obtained by energization of the reverse tape relay RT and completes an energizing circuit for the coil of parity relay P. Thereafter, the reverse read operation is the same as that described in connection with the energization of reverse tape relay RT. Reverse reading with this manually initiated control can be interrupted at any time, simply by releasing the push button BR.

During forward tape feed by the indexing and feeding mechanism all of the contacts, F211, Zla, 83a, OLC and STla, in the circuit for the coil RCC of the reader clutch are closed so that latch 26 is retracted and shaft 23 may rotate. To obviate tape overload, should the rate of tape feed from the supply reel be insufficient for any reason, contacts OLC are provided and adjusted to open whenever the'tape loop is substantially completely removed These contacts are also controlled by tension arm 7 and are set to open after the contacts RI close. Normally these contacts will not operate and operate only to stop the tape feed mechanism in the event the supply reel feed should be inadequate.

Although but one embodiment of this invention has been herein illustrated and described, it will be appreciated by those skilled in the art that numerous changes in this invention both as to the details of the disclosed arrangements and as to the organization of the details may be made. By way of example, reference is made to the use of two levers 34 and 35 to actuate the respective forward and reverse drive links 41 and 42. Obviously a single linkage may be utilized involving only one lever such as 34, having the respective drive links pivoted at a common point adj acent the free extremity thereof so that each has the same stroke for driving the ratchet wheel. This and other equally obvious expedients will be apparent to those skilled in the art.

What is claimed is:

1. Apparatus for incrementally displacing a member I to be controlled in forward and reverse directions, comprising; a driven member; a toothed ratchet wheel connected to drive said driven member; respective drive links disposed on opposite sides of said ratchet wheel and having extremities disposed to engage the teeth of said ratchet wheel; unidirectional rotary drive means connected to drive said drive links between two positions,-one a retracted position and the other a driving position, with respect to said ratchet wheel; a shift mechanism open able between two positions, selectively controlling engagement of said drive links with said ratchet wheel;

electromagnetic means controlling rnjovement of said shift mechanism between said two positions; mechanical means operable, to stop said drive means with said drive links in retracted position; electromagnetic means controlling said mechanical means; and circuit means con- The circuit for energizing take-up reel motor TRM for '7 trolling both said electromagnetic means to efiect operaticn of said mechanical means to stop said drive means and thereafter to effect operation of said shift mechanism from one of said two positions to the other of said two positions.

2. A reversible incremental mechanical drive comprising; a toothed ratchet wheel; pivotally mounted lever' means; drive means connected with said lever means for 15 angularly displacing said lever means between two positions;,a pair of drive links pivotally connected to said lever means to. be actuated thereby and having respective free extremities disposed on opposite sides of said ratchet wheel and adapted to engage said ratchet wheel; spring means engaging each drive link and biasing each drive link in a direction to engage said respective extremities with said ratchet wheel; and a movable shift lever having a portion disposed between said drive links and defining a pair of spaced edges slidably engageable with respective cooperating portions of said drive links; in one position of said shift'lever, one edge maintaining the associated wheel; in the other position of said shift lever, the other edge maintaining the associated drive link out of engagement with said ratchet wheel; both drive links when retracted riding said respective edges in disengaged relation with said ratchet wheel; 7

3. A reversible incremental mechanical drive comprising; a toothed ratchet wheel; pivotally mounted lever means; drive means connected with said lever means for angularly displacing said lever means between two positions; a pair of drive links pivotally connected to said lever means to be actuated thereby and having respective free extremities disposed on opposite sides of said ratchetlwheel and adapted to engage said ratchet wheel;

c drive link completely out of engagement with said ratchet associated drive link completely out of engagement with said ratchet wheel; in the other position of said shift lever, the other edge maintaining the associated drive link out of engagement with said ratchet wheel; both drive links when retracted riding said respective edges in disengaged relationwith said ratchet wheel; and a spring loaded indexing member havinganextrernity rid-ingthe teeth spective free extremities disposed'on opposite sides of said ratchet wheel and adapted to engage said ratchet wheel; spring means engaging each drive link and biasing each drive link in adirection to engage said respective extremities with said ratchet wheel; a movable shift lever having a portion disposed-between said drive links and defining a pair of spaced edges slidably engagable with respective cooperating portions of said drive links; in one position of said shift lever, one edge maintaining the as sociated drive link completely out of engagement with said ratchet wheel; in the other position of said shift lever, the otherredge maintaining the associated drive link out of engagement with said ratchet wheel; both drive links when retracted riding said respective edges in disengaged relation with said ratchet wheel; electromagnetically operated means connected to actuate said shift lever; and circuit means connected to control. said electromagnetically operated means only when said ,drive linksare retracted.

5; A reversible incremental mechanical drive comprising; a toothed ratchet wheel; pivotally mounted lever means; drive means connected with said lever means for angularly displacing said lever means between two positions; a pair of drive links pivotally connected to said lever means to be actuated thereby and having respective free extremities disposed on opposite sidesof said ratchet wheel and adapted to engage said ratchet Wheehspring means engaging each drive link and biasing each drive link in a direction to engage-said respective extremities with said ratchet wheel; a movable shift lever having a portion disposed between said drive links and defining a pair of spaced edges slidably'engagable with respective cooperating portions of sa'id drive links; in one position of said shift lever, one edge maintaining the associated drive link completely out of engagement with said ratchet wheel; in the other position of said shift lever, the other edge maintaining the associated drive link out of engagement with said ratchet wheel;both'drive links when retracted riding said respective edges in'disengag ed relation with said ratchet wheel; a clutch connected to said drive means and operable to stop saiddrive means with said drive links retracted; electromagnetically operated means connected to actnate said shift lever; and circuit means connected to control 'said electromagnetically operated 'rneans after stopping of said drive means.

References Cited in the file of this patent 2,668,012 f Lindeman Feb. 2,

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