US3026743A - Memory wheel - Google Patents

Memory wheel Download PDF

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US3026743A
US3026743A US22525A US2252560A US3026743A US 3026743 A US3026743 A US 3026743A US 22525 A US22525 A US 22525A US 2252560 A US2252560 A US 2252560A US 3026743 A US3026743 A US 3026743A
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pins
read
wheel
memory
station
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US22525A
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Myron S Curtis
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Warner and Swasey Co
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Warner and Swasey Co
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16HGEARING
    • F16H53/00Cams ; Non-rotary cams; or cam-followers, e.g. rollers for gearing mechanisms
    • F16H53/02Single-track cams for single-revolution cycles; Camshafts with such cams
    • F16H53/04Adjustable cams
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H43/00Time or time-programme switches providing a choice of time-intervals for executing one or more switching actions and automatically terminating their operations after the programme is completed
    • H01H43/02Details
    • H01H43/04Means for time setting
    • H01H43/06Means for time setting comprising separately adjustable parts for each programme step, e.g. with tappets
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T74/00Machine element or mechanism
    • Y10T74/21Elements
    • Y10T74/2101Cams
    • Y10T74/2102Adjustable
    • Y10T74/2105Memory devices

Definitions

  • a rotatable locking member having a circular periphery is supported eccentrically with respect to the circular array of pins and engages the pins as they are moved into read-out position to lock the pins against axial movement.
  • the locking member is supported for radial movement toward and from the point of engagement with the array of pins and is urged toward engagement with the array of pins at the read-out point.
  • FIG. 1 is a sectional View ⁇ through ⁇ a memory wheel device embodying the present invention and taken approximately along line 1-1 of FIG. 2, looking in the direction of the arrows;
  • FIG. 2 is a sectional view of the memory wheel device of FIG. l taken approximately along line 2--2 of FIG. 1 and looking in the direction of the arrows;
  • FIG. 3 is a fragmentary sectional view taken approximately along line 3-3 of FIG. 2 and looking in the direction of the arrows;
  • FIG. 4 is a sectional view through a memory Wheel device embodying the present invention but of a different construction than the device shown in FIGS. 1-3;
  • FIG. 5 is a sectional view through the memory wheel device of FIG. 4 taken approximately along line 5 5 of FIG. 4 and looking in the direction of the arrows.
  • the memory wheel device shown in FIGS. 1-3 comprises a wheel 10 rotatably supported within a casing 12 having side walls 13, 14, as well as top and bottom walls.
  • the memory wheel is keyed to a shaft 16 rotatably supported in the side wall 13 and extending both inwardly and outwardly thereof.
  • the outer end of the shaft 16 has a gear 17 keyed thereto, the gear 17 being driven to effect a rotation of the memory wheel 10.
  • the memory wheel 10 comprises a hub 20 which is fast on the shaft 16 and a radial flange 21 which extends radially from the side of the hub adjacent the inner end of shaft 16.
  • An annular ange 22 extends axially from the radial ange 21 at the outer periphery thereof and in a direction away from the hub 20 and the outer end of the flange 22 is turned inwardly to provide an annular inturned portion 23.
  • the inturned portion 23 could be a separate piece if desired.
  • the annular inturned portion 23 and the radial flange 21 are provided with a plurality of pairs of aligned openings 24 arranged in a circular array with each pair of aligned openings 24 receiving a memory pin 26.
  • Each memory pin 26 is slidable in the correspondingr openings 24 and extends axially out- Mice wardly of each side of the wheel 10, i.e., outwardly from the radial flange 21 and outwardly from the inturned annular portion 23.
  • the radial llange 21 and the inturned annular portion 23 dene an inwardly facing channel 28 and there is a clearance space between the bottom of the channel 2S and the pins 26.
  • a band of friction material 30 Disposed in the clearance between the bottom of Vthe channel 28 and the pins 26 is a band of friction material 30, which is preferably a feltlike material and which frictionally engages the pins 26 to resist displacement thereof.
  • the pins 26 are displaced axially at an input station to set the pins in a position indicative of the magnitude of the condition to be remembered and the pins, when moved to the read-out station, position a read-out member in accordance with the axial position of the pins.
  • the pins are set at an input, or read-in, station 32 and are then moved to a read-out station 33.
  • the input station 32 is located adjacent the right-hand side of the Wheel 10, as the latter is viewed in FIG. 1 and the read-in station is shown in detail in FIG. 3.
  • the read-in station comprises a triangularly-shaped, or wedge-shaped setting member 36 having a rounded apex portion 37 adapted to engage the right-hand end of the pins 26, as the latter are viewed in FIG. 1, and ⁇ the leftahand ends of the pins, as viewed in FIG. 3 to shift the pins from a datum position.
  • the setting member 36 is secured to the inner end of a rod 38 slidably supported in a boss 40 formed in the side 14 of the casing 12 and extends outwardly of the casing.
  • the rod 38 is axially movable to position the setting member 36.
  • the rounded apex of the setting member 36 is normally positioned in the path of the pins of the memory wheel and, as the pins are moved past the setting member 36 upon rotation of the wheel 10, the pins engage the rounded apex 37 and are moved inwardly to displace the pins axially a distance corresponding to the position of the setting member 36.
  • the axial position of the pins 26 after passing the setting member 36 is indicative of the position of the setting member at the time that the pins pass the rounded apex 37.
  • the rod 38 is urged axially to move the setting member 36 away from the pins 26 by a spring 42 disposed about the shaft 38 outwardly of the boss 40.
  • the spring 42 engages a washer 43 held on the shaft by a nut 44 threaded onto a reduced portion of the shaft.
  • Ihe outer end of the shaft 38 engages an input member 46 which is displaced in accordance with the condition which varies and which is to be recorded on the memory wheel 10.
  • the shaft 38 is moved inwardly and the pins 26 are set farther to the right, as the latter are viewed in FIG. 3, by the setting member 36 and if the member 46 is moved away from the memory device, the shaft 38 follows by reason of the spring 42 and the pins 26 are not set as far inwardly as was previously the case.
  • the pins 26 When the pins 26 are carried by the Wheel to the read-out station 33 upon rotation of thewheel in a counterclockwise direction as viewed in FIG. 2, they engage a rounded head 50 of a read-out member 51.
  • the pins 26 position the read-out member 51 as they move thereby with the read-out member 51 being urged toward engagement with the adjacent ends of the pins 26.
  • the read-out member 51 is disposed on the same side of the wheel as the input station 32.
  • the read-out member 51 in addition to the head 50, includes a rodlike portion 53 which is supported in a boss 54 in the side 14 of the casing l2 so as to be movable axially relative to the casing.
  • the outer end of the rodlike portion 53 engages an arm of a pivoted lever 55 which is operated about its pivot by the movement of the readout member S1.
  • the read-out member 51 is urged toward the pins 26 by spring means which is indicated as comprising a spring 56 disposed between the lever 55 anda frame member 57.
  • the read-out member will apply a force to the pins which will tend to shift the pins axially. This, however, .would destroy rthe setting of the pins.
  • the pins are locked yin their axial position as they move into their read-out position by a rotatable circular locking member or disk 6.9 supported eccentrically with respect to the circular array of pins 26 and disposed to engage the pins at the readout station.
  • thevcircular locking member 60 is disposed within the annular flange 22 and inside of the array of pins 26.
  • the lockingv member 6) has a smaller diameter than that of the circular array of pins 26 and is supported with itsk axis offsetv from .the axis of the wheel 10 and that of ythe circular array vof pins so that the periphery of the locking member ⁇ 60- engages the pins 26 as they move into the read-out station.
  • the locking member 60 is rotatably supported on a shaft 62 by a ball bearing 63.
  • the shaft p 62 is mounted in a carrier Vblock 64 supported for movement byguide rods 65, 66.
  • the guide rods 65, 66 extend parallel rto the radius of the circular locking member 69 through .the point of engagement of the locking memberwith the pin 26 at the read-out station and support the carrier block .63 and, in turn, the locking member 60 for4 radial movement toward and away from engagement with the pin at the read-out station.
  • the guide rods 65, 66 are, in :the illustrated embodiment, supported between vertically spaced shelves 67 extending outwardly fromsthe inner side of the side wall 14 and a spring Y63 is disposed about each of the guide rods 6.5, V66 andthe lower shelf 67 and urge the carrier block 64 and, in turn, the locking member 60 toward engagement with the pins at the read-out station.
  • An auxiliary spring 69 may be ⁇ disposed betweenthe block 64 and lower shelf 67, if desired.
  • the outer periphery of the locking disk 60 is urged into engagement withthe pin at the read-out station 33 and will frictionally engage the pin to resist axial movement of the pin due to the forces applied .by the read-out disk 51.
  • the periphery of ⁇ the locking disk 60 may be providedwith ya band of frictional material 72. Because of the different diameters of the circular larray of pins and of the llocking disk 60, the pins are clear of the locking disk before and after the read-out station. To facilitate movement ofthe pins to and from the read-out station 33, the locking disk 60 is capable of rotation with the pins.
  • the lefthand ends of the pins engage a reset cam 75 supported adjacent Vthe left-hand side ofthe memory Wheel 10, as the latter is viewed in FIG. 1.
  • the reset cam 75 has an inclined surface 76 which causes the pins to be reset to a predetermined datum position with respect to the memory wheel'1i to position the pins to again be displaced by the setting member 36.
  • FIGS. 4 and 5 a memory wheel device is shown therein which embodies certainy features of the present invention but which is of somewhat different construction ⁇ from that shown in FIGS. 1 to 3.
  • a memory wheel 180 is iixed to a shaft 81 rotatably supported in a side wall 82 of a casing 83 which houses the Wheel 80.
  • the Wheel 80 has an annular U-shaped groove 86 in the periphery thereof which defines an outwardly facing channel and a plurality of memory pins ⁇ 87 are arranged in a circular array about the memory wheel S0 and each of which pass ,through aligned openings in the side walls of the annular groove 86 to extend outwardly of both sides of the memory wheel.
  • the pins are set by a setting member 90 as they pass a read-in station 92 located adjacent the left-hand side of the wheel, as the wheel is viewedV same as the irstdescribed embodiment, with the excep-V tion that the setting and read-out stations are on opposite sides of the memory wheel.
  • a member supported eccentrically with respect to the circular array of the pins of the memory Wheel 80 is provided for locking the pins in position as they moveto the read-out station.
  • the locking member comprises a ring 96 which is of larger diameter than the outside diameter of the circular array of pins 87 and which is adapted to be received in the annular groove 86.
  • the inner periphery of the ring 96 engages Vthe pin in read-out position to frictionally hold the pin and .the inner periphery may comprise a friction band 96a.
  • the read-out station is, in the illustrated embodiment, at the uppermost point of the memory Wheel Sti and the ring 96 hangs ⁇ on'the pins 87 at the top of the memory wheel.
  • the ring 96 is urged into engagement with the array of pins S7 at the top of the memory wheel, Vi.e., at the read-out station, by .a pair of rollers 97 supported in a yoke 98 and urged yby a spring 100 into engagement with the outer periphery of the ring 96 at the read-out station.
  • the spring is disposed in a boss lill' extending upwardly from the top of the casing S3 and engages a rodr102, which extends upwardly from the yoke 98 and urges the rod 102, the yoke 98, and the rollers 97 downwardly toward engagement With the outer periphery of the ring 96.
  • the present invention provides a new and an improved memory wheel device including a plurality of pins supported in a circular array and means for locking the pins in an axial position as the pins are moved past a read-out station. While embodiments have been described in detail, further modifications, constructions, and arrangements will be apparent to those skilled in the art and it is hereby my intention to cover all such modifications, constructions, and arrangements which fall Within the ability of those skilled in the art and Within the scope and spirit of Vthe present invention.
  • a memory wheel device comprising a rotatable wheel having a plurality of axially extending memory pins a1'- ranged in a circular array about the axis of the Wheel, said pins extending outwardly of each side of said wheel, ⁇ an input station adjacent said wheel, means at said input station for variably displacing the pins of said Wheel axially as said pins are moved past said station upon rota- In the embodiment of FIGS.
  • a memory wheel device comprising a rotatable wheel having a plurality of axially extending memory pins arranged in a circular array about the axis of the wheel, said pins extending outwardly of each side of said wheel, an input station adjacent said Wheel, means at said input station for selectively displacing the pins of said wheel axially as said pins are moved past said station upon rotation of said wheel, a read-out station adjacent said wheel including a read-out member urged into engagement with the end of the pin at said read-out station, means at said read-out station for locking said pins against axial movement while engaged by said read-out member comprising a circular locking disk of smaller diameter than said circular array, and support means rotatably mounting said locking disk within said array and eccentrically with respect to said ⁇ array with the outer periphery of said locking disk engaging said pins when said pins are in position to be engaged by said read-out member at said read-out station, said support means including means supporting said locking disk for radial movement toward and away from
  • a memory wheel device comprising a hub having a radial flange extending radially outwardly from the hub and an annular flange extending axially outwardly from said radial flange at the outer periphery of said radialV llange, said annular liange having a radial inwardly extending outer end part which denes with said radial and annular flanges an annular channel opening inwardly of said wheel, said pins being slidably received in aligned bores in said radial llange and said end part and extending across said channel, said disk being disposed within said annular flange and engaging the inner side of said array of pins.
  • Atmemory wheel device as dened in claim 3 where- Y Y in a band of friction material: is closely fitted between said H pins and the bottom of said channel.
  • Y read-out station fortlocking said pins against axial move- Vment While engaged by said read-out member comprising a circularlocking disk of smaller diameter than said circular array, andsupportmeans rotatably mounting said Vlocking disk within said arrayfan'd eccentrically with-respect to said array with Vthe outer periphery of said .locke ing disk engaging said pins when said pins are in position to be engaged by said read-out member at said lread-out station, said support means comprising a carrier block, a shaft extending parallel to the axis of said array but offset therefrom mounted on said block and rotatably supporting said disk, means supporting said block for movement parallel to the radius of said disk through a pin at said read-out station, and spring means yieldably urging said carrier block toward said read-out station.
  • a memory wheel device yaccording to claim 5 wherein said wheel comprises a hub having a radial flange extending radially outwardly from the hub at one end thereof and an annular flange extending axially outwardly away from said one end at the outer periphery of said radial ange, said annular flange having a radial inwardly extending outer end part which denes with said radial and annular flanges an annular channel opening inwardly of said wheel, said pins being slidably received in aligned bores in said radial flange and said end part and extending across said channel, said disk being disposed within said annular ilange and engaging the inner side of said array of pms.
  • a memory wheel device comprising. a rotatable wheel having a plurality of axially extending memory pins arranged in a circular array about the axis of the wheel, said pins extending outwardly of each side of said wheel, an input station adjacent said wheel, means at said input station for variably displacing the pins of said wheel axially to set the pins in accordance with a Variable condition as said pins are moved past said station upon rotation of said wheel, a read-out station adjacent said wheel including a read-out member urged into engagement with the end of the pins when in read-out position, means at said read-out station for locking said pins against axial movement while in engagement with said readout member comprising a rigid rotatable locking ring of larger inside diameter than said circular array and disposed about said array of pins, the inner periphery of said ring engaging the pins when at said read-out station, and biasing means urging said ring into engagement with said array of pins at said read-out station and supporting said ring
  • a memory wheel device as dened in claim 8 wherein said ring is supported by said array of pins and by roller means comprising a part of said biasing means and engaging the outer periphery of said ring at said readout station, said roller means being supported for movement toward and away from said ring and said biasing means including a spring acting to urge said roller means into engagement with said ring.
  • a memory device as dened in claim 8 wherein said wheel rotates in a vertical plane and said read-out station is at the top of the wheel and said ring is hung on the top of said array of pins.
  • a memory device as defined in claim 10 wherein said biasing means comprises la roller which engages the outside periphery of said locking ring at said read-out station and a spring acting on said roller and urging it toward said array.

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  • Mechanical Engineering (AREA)
  • Time Recorders, Dirve Recorders, Access Control (AREA)

Description

March 27, 1962 M. s. CURTIS 3,025,743
MEMORY WHEEL Filed April l5, 1960 2 Sheets-Sheet 1 ATTORNEYS March 27, 1962 M. s. CUR-ns MEMORY WHEEL 2 Sheets-Sheet 2 Filed April l5, 1960 s Rw wm we. m m5 JDN" Wm vl M @,A YM B m vgl United States Patent O 3,026,743 MEMORY WHEEL Myron S. Curtis, Cleveland, Ohio, assignor to The Warner & Swasey Company, Cleveland, Ohio, a corporation of Filed Apr. 15, 1960, Ser. No. 22,525 11 Claims. (Cl. 74-568) improved means for locking the pins against movement` at a read-out station, which locking means is sure in operation and is of compact, relatively simple construction.
In accordance with one feature of the present invention, a rotatable locking member having a circular periphery is supported eccentrically with respect to the circular array of pins and engages the pins as they are moved into read-out position to lock the pins against axial movement. The locking member is supported for radial movement toward and from the point of engagement with the array of pins and is urged toward engagement with the array of pins at the read-out point.
Further objectsy and advantages of the present invention will be apparent from the following detailed description of the preferred embodiment thereof made with reference to the accompanying drawings forming a part of the present specification in which:
FIG. 1 is a sectional View `through `a memory wheel device embodying the present invention and taken approximately along line 1-1 of FIG. 2, looking in the direction of the arrows;
FIG. 2 is a sectional view of the memory wheel device of FIG. l taken approximately along line 2--2 of FIG. 1 and looking in the direction of the arrows;
FIG. 3 is a fragmentary sectional view taken approximately along line 3-3 of FIG. 2 and looking in the direction of the arrows;
FIG. 4 is a sectional view through a memory Wheel device embodying the present invention but of a different construction than the device shown in FIGS. 1-3; and
FIG. 5 is a sectional view through the memory wheel device of FIG. 4 taken approximately along line 5 5 of FIG. 4 and looking in the direction of the arrows.
l Referring to the drawings, the memory wheel device shown in FIGS. 1-3 comprises a wheel 10 rotatably supported within a casing 12 having side walls 13, 14, as well as top and bottom walls. The memory wheel is keyed to a shaft 16 rotatably supported in the side wall 13 and extending both inwardly and outwardly thereof. The outer end of the shaft 16 has a gear 17 keyed thereto, the gear 17 being driven to effect a rotation of the memory wheel 10.
The memory wheel 10 comprises a hub 20 which is fast on the shaft 16 and a radial flange 21 which extends radially from the side of the hub adjacent the inner end of shaft 16. An annular ange 22 extends axially from the radial ange 21 at the outer periphery thereof and in a direction away from the hub 20 and the outer end of the flange 22 is turned inwardly to provide an annular inturned portion 23. The inturned portion 23 could be a separate piece if desired. The annular inturned portion 23 and the radial flange 21 are provided with a plurality of pairs of aligned openings 24 arranged in a circular array with each pair of aligned openings 24 receiving a memory pin 26. Each memory pin 26 is slidable in the correspondingr openings 24 and extends axially out- Mice wardly of each side of the wheel 10, i.e., outwardly from the radial flange 21 and outwardly from the inturned annular portion 23. The radial llange 21 and the inturned annular portion 23 dene an inwardly facing channel 28 and there is a clearance space between the bottom of the channel 2S and the pins 26. Disposed in the clearance between the bottom of Vthe channel 28 and the pins 26 is a band of friction material 30, which is preferably a feltlike material and which frictionally engages the pins 26 to resist displacement thereof.
In memory devices of the type shown in the drawings the pins 26 are displaced axially at an input station to set the pins in a position indicative of the magnitude of the condition to be remembered and the pins, when moved to the read-out station, position a read-out member in accordance with the axial position of the pins. In the device shown in FIGS. l-3, the pins are set at an input, or read-in, station 32 and are then moved to a read-out station 33. The input station 32 is located adjacent the right-hand side of the Wheel 10, as the latter is viewed in FIG. 1 and the read-in station is shown in detail in FIG. 3.
As is best shown in FIG. 3, the read-in station comprises a triangularly-shaped, or wedge-shaped setting member 36 having a rounded apex portion 37 adapted to engage the right-hand end of the pins 26, as the latter are viewed in FIG. 1, and `the leftahand ends of the pins, as viewed in FIG. 3 to shift the pins from a datum position. The setting member 36 is secured to the inner end of a rod 38 slidably supported in a boss 40 formed in the side 14 of the casing 12 and extends outwardly of the casing. The rod 38 is axially movable to position the setting member 36. The rounded apex of the setting member 36 is normally positioned in the path of the pins of the memory wheel and, as the pins are moved past the setting member 36 upon rotation of the wheel 10, the pins engage the rounded apex 37 and are moved inwardly to displace the pins axially a distance corresponding to the position of the setting member 36. The axial position of the pins 26 after passing the setting member 36 is indicative of the position of the setting member at the time that the pins pass the rounded apex 37.
The rod 38 is urged axially to move the setting member 36 away from the pins 26 by a spring 42 disposed about the shaft 38 outwardly of the boss 40. The spring 42 engages a washer 43 held on the shaft by a nut 44 threaded onto a reduced portion of the shaft. Ihe outer end of the shaft 38 engages an input member 46 which is displaced in accordance with the condition which varies and which is to be recorded on the memory wheel 10.
- If the member 46 is moved toward the memory device,
the shaft 38 is moved inwardly and the pins 26 are set farther to the right, as the latter are viewed in FIG. 3, by the setting member 36 and if the member 46 is moved away from the memory device, the shaft 38 follows by reason of the spring 42 and the pins 26 are not set as far inwardly as was previously the case.
When the pins 26 are carried by the Wheel to the read-out station 33 upon rotation of thewheel in a counterclockwise direction as viewed in FIG. 2, they engage a rounded head 50 of a read-out member 51. The pins 26 position the read-out member 51 as they move thereby with the read-out member 51 being urged toward engagement with the adjacent ends of the pins 26. In the illustrated embodiment, the read-out member 51 is disposed on the same side of the wheel as the input station 32.
The read-out member 51, in addition to the head 50, includes a rodlike portion 53 which is supported in a boss 54 in the side 14 of the casing l2 so as to be movable axially relative to the casing. The outer end of the rodlike portion 53 engages an arm of a pivoted lever 55 which is operated about its pivot by the movement of the readout member S1. The read-out member 51 is urged toward the pins 26 by spring means which is indicated as comprising a spring 56 disposed between the lever 55 anda frame member 57.
As the pins move into engagement with the read-out mem-ber `51, the read-out member will apply a force to the pins which will tend to shift the pins axially. This, however, .would destroy rthe setting of the pins. In accordance with 4the present invention, the pins are locked yin their axial position as they move into their read-out position by a rotatable circular locking member or disk 6.9 supported eccentrically with respect to the circular array of pins 26 and disposed to engage the pins at the readout station. As is best shown in FIG. l, thevcircular locking member 60 is disposed within the annular flange 22 and inside of the array of pins 26. The lockingv member 6) has a smaller diameter than that of the circular array of pins 26 and is supported with itsk axis offsetv from .the axis of the wheel 10 and that of ythe circular array vof pins so that the periphery of the locking member` 60- engages the pins 26 as they move into the read-out station. The locking member 60 is rotatably supported on a shaft 62 by a ball bearing 63. The shaft p 62 is mounted in a carrier Vblock 64 supported for movement byguide rods 65, 66. The guide rods 65, 66 extend parallel rto the radius of the circular locking member 69 through .the point of engagement of the locking memberwith the pin 26 at the read-out station and support the carrier block .63 and, in turn, the locking member 60 for4 radial movement toward and away from engagement with the pin at the read-out station. g
The guide rods 65, 66 are, in :the illustrated embodiment, supported between vertically spaced shelves 67 extending outwardly fromsthe inner side of the side wall 14 and a spring Y63 is disposed about each of the guide rods 6.5, V66 andthe lower shelf 67 and urge the carrier block 64 and, in turn, the locking member 60 toward engagement with the pins at the read-out station. An auxiliary spring 69 may be `disposed betweenthe block 64 and lower shelf 67, if desired.
From the foregoing description, it can be seen that the outer periphery of the locking disk 60 is urged into engagement withthe pin at the read-out station 33 and will frictionally engage the pin to resist axial movement of the pin due to the forces applied .by the read-out disk 51. If desired, the periphery of` the locking disk 60 may be providedwith ya band of frictional material 72. Because of the different diameters of the circular larray of pins and of the llocking disk 60, the pins are clear of the locking disk before and after the read-out station. To facilitate movement ofthe pins to and from the read-out station 33, the locking disk 60 is capable of rotation with the pins.
After the pins 26'pass the read-out station 33, the lefthand ends of the pins engage a reset cam 75 supported adjacent Vthe left-hand side ofthe memory Wheel 10, as the latter is viewed in FIG. 1. The reset cam 75 has an inclined surface 76 which causes the pins to be reset to a predetermined datum position with respect to the memory wheel'1i to position the pins to again be displaced by the setting member 36.
' Referring to FIGS. 4 and 5, a memory wheel device is shown therein which embodies certainy features of the present invention but which is of somewhat different construction `from that shown in FIGS. 1 to 3. In the memory wheeldevice of FIGS. 4 and 5, a memory wheel 180 is iixed to a shaft 81 rotatably supported in a side wall 82 of a casing 83 which houses the Wheel 80. The Wheel 80 has an annular U-shaped groove 86 in the periphery thereof which defines an outwardly facing channel and a plurality of memory pins` 87 are arranged in a circular array about the memory wheel S0 and each of which pass ,through aligned openings in the side walls of the annular groove 86 to extend outwardly of both sides of the memory wheel. The pins are set by a setting member 90 as they pass a read-in station 92 located adjacent the left-hand side of the wheel, as the wheel is viewedV same as the irstdescribed embodiment, with the excep-V tion that the setting and read-out stations are on opposite sides of the memory wheel.
In accordance with one feature of the present invention, a member supported eccentrically with respect to the circular array of the pins of the memory Wheel 80 is provided for locking the pins in position as they moveto the read-out station. and 5, the locking member comprises a ring 96 which is of larger diameter than the outside diameter of the circular array of pins 87 and which is adapted to be received in the annular groove 86. The inner periphery of the ring 96 engages Vthe pin in read-out position to frictionally hold the pin and .the inner periphery may comprise a friction band 96a. The read-out station is, in the illustrated embodiment, at the uppermost point of the memory Wheel Sti and the ring 96 hangs `on'the pins 87 at the top of the memory wheel. The ring 96 is urged into engagement with the array of pins S7 at the top of the memory wheel, Vi.e., at the read-out station, by .a pair of rollers 97 supported in a yoke 98 and urged yby a spring 100 into engagement with the outer periphery of the ring 96 at the read-out station. The spring is disposed in a boss lill' extending upwardly from the top of the casing S3 and engages a rodr102, which extends upwardly from the yoke 98 and urges the rod 102, the yoke 98, and the rollers 97 downwardly toward engagement With the outer periphery of the ring 96. It will be readily -understood that the pressure of the spring `litt) acting -on the pins through the ring 96'will lock the pins against axial movement as they are rotated to the read-out position and because of the eccentric nature of the inner periphery of the ring and the circular array of pins, the Vpins S7 will be free'to move axially, insofar as the ring96 is concerned, both before and after the read-out station. It will be understood that the ring 96 may engage more than one pin as the pins approach the read-out station. Furthermore, since the ring 96 is capable of movement,
whenthe force between the pins and ring 96 reaches a From the `foregoing description, it can be seen that the present invention provides a new and an improved memory wheel device including a plurality of pins supported in a circular array and means for locking the pins in an axial position as the pins are moved past a read-out station. While embodiments have been described in detail, further modifications, constructions, and arrangements will be apparent to those skilled in the art and it is hereby my intention to cover all such modifications, constructions, and arrangements which fall Within the ability of those skilled in the art and Within the scope and spirit of Vthe present invention.
Having described my invention, I claim:
1. A memory wheel device comprising a rotatable wheel having a plurality of axially extending memory pins a1'- ranged in a circular array about the axis of the Wheel, said pins extending outwardly of each side of said wheel, `an input station adjacent said wheel, means at said input station for variably displacing the pins of said Wheel axially as said pins are moved past said station upon rota- In the embodiment of FIGS. 4 'l tion of said wheel -to set the pins in accordance with a variable condition, a read-out station adjacent said wheel, means at said read-out static .1 for locking said pins against axial movement comprising a substantially rigid circular locking member of diierent diameter from said circular array, support means mounting said locking member eccentrically with respect to said array of pins with the periphery of said lock-ing member engaging said array of pins at said read-out station and rotatably supporting said locking member, said support means including means supporting said locking member for radial movement toward and away from its point of engagement with said array of pins at said read-out station and means yieldably urging said locking member into engagement with said pins at said read-out station.
2. A memory wheel device comprising a rotatable wheel having a plurality of axially extending memory pins arranged in a circular array about the axis of the wheel, said pins extending outwardly of each side of said wheel, an input station adjacent said Wheel, means at said input station for selectively displacing the pins of said wheel axially as said pins are moved past said station upon rotation of said wheel, a read-out station adjacent said wheel including a read-out member urged into engagement with the end of the pin at said read-out station, means at said read-out station for locking said pins against axial movement while engaged by said read-out member comprising a circular locking disk of smaller diameter than said circular array, and support means rotatably mounting said locking disk within said array and eccentrically with respect to said `array with the outer periphery of said locking disk engaging said pins when said pins are in position to be engaged by said read-out member at said read-out station, said support means including means supporting said locking disk for radial movement toward and away from its point or engagement with said array of pins at said read-out station and means yieldably urging said locking member toward engagement with the pin at said read-out station.
3. A memory wheel device according tto claim 2 wherein said wheel comprises a hub having a radial flange extending radially outwardly from the hub and an annular flange extending axially outwardly from said radial flange at the outer periphery of said radialV llange, said annular liange having a radial inwardly extending outer end part which denes with said radial and annular flanges an annular channel opening inwardly of said wheel, said pins being slidably received in aligned bores in said radial llange and said end part and extending across said channel, said disk being disposed within said annular flange and engaging the inner side of said array of pins.
4. Atmemory wheel device as dened in claim 3 where- Y Y in a band of friction material: is closely fitted between said H pins and the bottom of said channel.
Y read-out station fortlocking said pins against axial move- Vment While engaged by said read-out member comprising a circularlocking disk of smaller diameter than said circular array, andsupportmeans rotatably mounting said Vlocking disk within said arrayfan'd eccentrically with-respect to said array with Vthe outer periphery of said .locke ing disk engaging said pins when said pins are in position to be engaged by said read-out member at said lread-out station, said support means comprising a carrier block, a shaft extending parallel to the axis of said array but offset therefrom mounted on said block and rotatably supporting said disk, means supporting said block for movement parallel to the radius of said disk through a pin at said read-out station, and spring means yieldably urging said carrier block toward said read-out station.
6. A memory wheel device yaccording to claim 5 wherein said wheel comprises a hub having a radial flange extending radially outwardly from the hub at one end thereof and an annular flange extending axially outwardly away from said one end at the outer periphery of said radial ange, said annular flange having a radial inwardly extending outer end part which denes with said radial and annular flanges an annular channel opening inwardly of said wheel, said pins being slidably received in aligned bores in said radial flange and said end part and extending across said channel, said disk being disposed within said annular ilange and engaging the inner side of said array of pms.
7. A memory wheel device as deiined in claim 6 wherein a band of friction material is closely fitted between said pins and the bottom of said channel.
8. A memory wheel device comprising. a rotatable wheel having a plurality of axially extending memory pins arranged in a circular array about the axis of the wheel, said pins extending outwardly of each side of said wheel, an input station adjacent said wheel, means at said input station for variably displacing the pins of said wheel axially to set the pins in accordance with a Variable condition as said pins are moved past said station upon rotation of said wheel, a read-out station adjacent said wheel including a read-out member urged into engagement with the end of the pins when in read-out position, means at said read-out station for locking said pins against axial movement while in engagement with said readout member comprising a rigid rotatable locking ring of larger inside diameter than said circular array and disposed about said array of pins, the inner periphery of said ring engaging the pins when at said read-out station, and biasing means urging said ring into engagement with said array of pins at said read-out station and supporting said ring for rotation.
9. A memory wheel device as dened in claim 8 wherein said ring is supported by said array of pins and by roller means comprising a part of said biasing means and engaging the outer periphery of said ring at said readout station, said roller means being supported for movement toward and away from said ring and said biasing means including a spring acting to urge said roller means into engagement with said ring.
10. A memory device as dened in claim 8 wherein said wheel rotates in a vertical plane and said read-out station is at the top of the wheel and said ring is hung on the top of said array of pins. Y
lll. A memory device as defined in claim 10 wherein said biasing means comprises la roller which engages the outside periphery of said locking ring at said read-out station and a spring acting on said roller and urging it toward said array.
t References Cited in the file of this patent i UNITED STATES PATENTS 2,686,415 Grin Aug. 1.7, 1954 2,767,788 .Parker Oct. 23, 1956 2,770,975 Galley Nov. 20, 1956 2,808,506- Skwarek Oct. l, 1957
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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3113350A (en) * 1960-05-18 1963-12-10 Warner Swasey Co Memory wheel control system for gill box
US3158121A (en) * 1960-03-03 1964-11-24 Motomation Inc Mechanical memory device
US3175422A (en) * 1962-05-16 1965-03-30 Aerojet General Co Memory storage pin detent means for electro-mechanical memories
US3206803A (en) * 1962-01-29 1965-09-21 Prince Smith & Stells Ltd Apparatus for detecting and correcting irregularities of thickness of a textile slive
US3279624A (en) * 1962-09-26 1966-10-18 George C Devol Programmed article handling
US4288020A (en) * 1979-07-02 1981-09-08 The Babcock & Wilcox Company Tracking type welding apparatus

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2686415A (en) * 1951-04-03 1954-08-17 Robert H Griffin Control mechanism
US2767788A (en) * 1951-12-19 1956-10-23 Coe Mfg Co Veneer clipper
US2770975A (en) * 1953-11-10 1956-11-20 Unilever Ltd Servo mechanisms
US2808506A (en) * 1953-03-24 1957-10-01 Polarad Electronics Corp Tracking mechanism for ganged radio circuits

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2686415A (en) * 1951-04-03 1954-08-17 Robert H Griffin Control mechanism
US2767788A (en) * 1951-12-19 1956-10-23 Coe Mfg Co Veneer clipper
US2808506A (en) * 1953-03-24 1957-10-01 Polarad Electronics Corp Tracking mechanism for ganged radio circuits
US2770975A (en) * 1953-11-10 1956-11-20 Unilever Ltd Servo mechanisms

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3158121A (en) * 1960-03-03 1964-11-24 Motomation Inc Mechanical memory device
US3113350A (en) * 1960-05-18 1963-12-10 Warner Swasey Co Memory wheel control system for gill box
US3206803A (en) * 1962-01-29 1965-09-21 Prince Smith & Stells Ltd Apparatus for detecting and correcting irregularities of thickness of a textile slive
US3175422A (en) * 1962-05-16 1965-03-30 Aerojet General Co Memory storage pin detent means for electro-mechanical memories
US3279624A (en) * 1962-09-26 1966-10-18 George C Devol Programmed article handling
US4288020A (en) * 1979-07-02 1981-09-08 The Babcock & Wilcox Company Tracking type welding apparatus

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