US3312238A - Monostable fluid logic element and actuator - Google Patents

Monostable fluid logic element and actuator Download PDF

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Publication number
US3312238A
US3312238A US421032A US42103264A US3312238A US 3312238 A US3312238 A US 3312238A US 421032 A US421032 A US 421032A US 42103264 A US42103264 A US 42103264A US 3312238 A US3312238 A US 3312238A
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Prior art keywords
tape
fluid
actuating
housing
cavity
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US421032A
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Jr William F Voit
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International Business Machines Corp
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International Business Machines Corp
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Priority to US421032A priority Critical patent/US3312238A/en
Priority to GB4737365A priority patent/GB1080109A/en
Priority to DE19651774810 priority patent/DE1774810B1/en
Priority to DE1965J0029417 priority patent/DE1296916B/en
Priority to DE19651523540 priority patent/DE1523540C/en
Priority to FR41674A priority patent/FR1469011A/en
Priority to FR41670A priority patent/FR1457217A/fr
Priority to NL6516771A priority patent/NL149573B/en
Priority to CH1780065A priority patent/CH438800A/en
Application granted granted Critical
Publication of US3312238A publication Critical patent/US3312238A/en
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F15FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
    • F15CFLUID-CIRCUIT ELEMENTS PREDOMINANTLY USED FOR COMPUTING OR CONTROL PURPOSES
    • F15C3/00Circuit elements having moving parts
    • 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
    • Y10T137/00Fluid handling
    • Y10T137/8158With indicator, register, recorder, alarm or inspection means
    • Y10T137/8175Plural
    • Y10T137/8192Unobvious - "combination lock" type
    • 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
    • Y10T137/00Fluid handling
    • Y10T137/8593Systems
    • Y10T137/86493Multi-way valve unit
    • Y10T137/86574Supply and exhaust
    • Y10T137/86622Motor-operated
    • Y10T137/8663Fluid motor
    • 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
    • Y10T74/18Mechanical movements
    • Y10T74/18992Reciprocating to reciprocating

Definitions

  • FIG. 4 w. F. VOIT, JR 3,312,238 MONOSTABLE ELUID LQGIC ELEMENT AND ACTUATOR 2 Sheets- Sheet 2 F iled Dec. 24, 1964 FIG. 4
  • FIG. 6 VALVED SOURCE.
  • the present invention relates generally to the logic and actuator arts and more particularly to the provision of fluid elements each having a single stable state which are capable of being used as actuators for mechanical apparatus and of performing various logic operations of the type usually accomplished by electrical components.
  • One such fluid element is the fluid jet amplifier wherein a stream of fluid issuing from a nozzle is directed to either of a pair of outlet ports.
  • the fluid jet is switched between the outlet ports by appropriately directed pressure gradients applied transversely across the fluid jet between the spaced nozzle and the pair of outlet ports.
  • the pressure gradients are provided through the use of fluid control streams, vacuums, electrical discharges or the like.
  • the fluid jet amplifier is a bistable device in that the fluid jet will remain directed toward a particular outlet port even though the controlling transverse pressure gradient is removed due to the boundary layer condition existing between the fluid jet and the adjacent side wall of the outlet port. 1
  • Fluid elements of the type mentioned above are relatively fast acting, occupy a minimum of space and can be fabricated at a low cost using conventional plastic molding techniques.
  • the fluid elements can be interconnected to perform complex logic functions and are highly reliable in the sense they do not wear out and require replacement as do conventional electrical components. While these advantages have been widely recognized, several problems have somewhat limited the use of such fluid elements.
  • a relatively large volume source of fluid under pressure is required siiice fluid is continuously moving through the fluid jet amplifiers and exhausted during standby conditions.
  • fluid jet amplifiers are load sensitive devices and various vents must be provided adjacent the outlet ports so that such amplifiers are not capable of performing much work.
  • the basic fluid element comprises a strip or tape of flexible material which is received in an elongated slot in a housing.
  • One end portion of the tape is stationarily mounted or anchored with respect tothe housing and the other end portion of the tape is free to move in the elongated slot.
  • a cavity is formed in the housing adjacent one side of the slot and an actuating port communicates with the slot on the opposite side of the tape from the cavity.
  • a pressure gradient is created between the actuating port and the bottom of the cavity whereby the portion of the tape overlying the cavity is forced into the cavity and the free end portion of the tape moves in the slot in the housing.
  • the material forming the tape, its mounting and dimensions, in combination with the dimensions and shape of the cavity are selected so that when the pressure gradient is removed the tape returns to its original position.
  • cut conditions are in communication with each other or blocked depending on whether the tape is in its actuated or initial at rest condition.
  • a plurality of tapes can be arranged in a single housing in generally overlying relation.
  • the apertures in the tapes are positioned or coded in a manner to provide for the accomplishment of relatively complicated logic functions, such as converting signals from one code to a different code.
  • the fluid element of the present invention also provides a transducing means for directly actuating mechanical elements in responseto applied fluid signals.
  • the movable free end portion of the tape is directly attached to a mechanical device to be moved.
  • the mechanical device is actuated in response to the application of the pressure gradient across the tape which causes the same to move into the cavity in the housing.
  • the fluid elements each comprise a strip or tape of flexible material which is movable longitudinally in a slot in a housing in response to applied fluid signals.
  • a cavity is formed in the housing adjacent the slot and the applied fluid signal forces the tape into the cavity to cause the longitudinal movement of the tape in the slot.
  • Another object of invention is the provision of a fluid
  • the material, size and mounting of the tape are such that the tape automatically returns from the cavity in the housing to its initial flat condition when the fluid input signal is removed.
  • Yet another object of the invention is to provide a fluid element that can be readily combined with other generally similar fluid elements to perform complicated logic functions.
  • a plurality of the strips or tapes are arranged The free end portion of the tape of the fluid element J in overlying relation.
  • Apertures corresponding to logic functions to be performed are provided in the movable ends of the strips for controlling the flow of fluid between various inlet and outlet ports.
  • Still another object of the invention is the provision of fluid elements capable of being interconnected to perform complicated logic functions wherein relatively low volume fluid supply means are required.
  • the fluid elements are relatively fluid tight and fluid, other than normal leakage, is not continuously exhausted during standby operations as is the case with conventional fluid jet amplifiers.
  • a further object of this invention is the provision of a fluid element or transducer adapted to be directly connected to and actuate mechanical elements.
  • the forcedisplacement curve associated with the actuator is such that a large force is available during the initial movement of the tape. This characteristic matches very closely the actuating requirements of a high mass load, such as the cycle clutch latch in a typewriter, for example.
  • Still a further object of the invention is to provide a logic element and/or actuator having the characteristics above described which is extremely simple in construction and operation.
  • the elements are formed employing conventional plastic molding techniques at low cost.
  • the fluid logic elements are highly reliable in operation and do not wear out as do analogous electrical components.
  • FIGURE 1 is a side sectional view showing a fluid ele- .ment constructed and operated in accordance with the .teachings of the present invention
  • FIGURE 2 is a side sectional view showing the fluid element of FIGURE 1 in its actuated and transient state;
  • FIGURE 3 is a side sectional view of another fluid element embodying the teachings of this invention.
  • FIGURE 4 is a side sectional view of a decoding device illustrating the manner in Which the fluid elements :may be combined to perform complicated logic functions;
  • FIGURE 5 is a schematic chart in which the tapes employed in the decoding device of FIGURE 4 are laid out vin side-by-side relation to better illustrate the cooperation 'of the tapes with each other in performing the decoding function;
  • FIGURE 6 is a side perspective view of a fluid element illustrating its use as a fluid-to-mechanical transducer for actuating a mechanical device
  • FIGURE 7 is a graph depicting the force versus displacement relationship for the tape of a fluid element during the actuation thereof.
  • the fluid element comprises a housing 11 of plastic or other similar material which is formed with an opening to provide a generally thin and rectangular elongated slot 12.
  • Received within the slot 1 2 is a flexible rectangular strip or tape 13 of plastic or metal, such as Mylar or strip steel for example.
  • the tape 13 is anchored to the housing 11 at one end by bolt '14 or any other convenient means and its other end is free to move in the slot 12.
  • a generally U-shaped cavity Formed in the housing 11 adjacent the anchored end of the tape 13 is a generally U-shaped cavity which communicates with the slot 12. The bottom of the cavity 15 is exhausted to atmosphere by a pair of exhaust ports 16.
  • an actuating port 17 Provided in the housing 11 on the opposite side of the slot 12 and tape 13 from the cavity 15 is an actuating port 17 which is in communication with a valved source of fluid under pressure represented schematically at 18 in the drawings.
  • the cavity 15 has approximately the same width dimension as that of the portion of the tape 13 received within the cavity so that fluid leakage is maintained at a minimum during and does not markedly effect the speed of operation of the device.
  • the free end portion 19 of the tape 13 moves through a linear distance correspondingdirectly to the length of tape required to conform to the bottom contour of the cavity 15.
  • the exhaust ports. 16 prevent the entrapment of fluid and the build up of fluid pressure between the bottom of the cavity 15 and the tape 13 so that the tape moves very quickly and smoothly into the cavity.
  • the movement of the tape 13 into the cavity 15 is caused by a pressure gradient which extends transversely of the tape as explained above.
  • the pressure gradient can be created I in various ways, including applying a fluid input pulse to one side of the tape 13 while exhausting the cavity 15 as employed in connection with the illustrated embodiments of the invention.
  • the exhaust ports 16 can be normally blocked and fluid under pressure always supplied to the actuating port 17. A condition of pressure equilibrium would then exist because of the nominal clearance between the edges of the tape and the cavity.
  • the tape 13 would remain in its unactuated state until the exhaust ports 16 are opened to create the tape deflecting pressure gradient.
  • Still another manner of providing the pressure gradient extending transversely of the tape 13 to deflect the same into the cavity is to apply vacuum to the exhaust ports 16.
  • the fluid element is a monostable device since it has a single stable state (the unactuated or initial state shown in FIGURE 1 of the drawings) and a transient unstable state (the actuated state shown in FIGURE 2 of the drawings) which exists only as long as an actuating pressure gradient extends transversely of the tape 13 to hold the same deflected in the cavity 15.
  • the source of fluid under pressure 18 is eflectively disconnected from the actuating port 17, the tape 13 automatically returns to its initial and flat condition without external assistance of any kind.
  • the tape employed was a piece of Mylar plastic having a thickness of three mils and a width of .312 of an inch. The cavity was approximately .80 of an inch long and .165 of an inch deep at its deepest point.
  • the thickness of the tape is selected so that the time required for the tape to automatically return to its initial and stable state is approximately the same as the time required to deflect the tape into the cavity. As a general rule, when the thickness is increased, the resetting action occurs at a faster'rate.
  • the design of the thickness of the tape provides a means for controlling the automatic re-- setting of the fluid element. Fluid elements'having the dimensions set forth above are actuated and automatically reset within time intervals in the range of three to six milliseconds.
  • Critical aspects of the design of a fluid element are the thickness dimension and mounting of the tape considering the use projected for the fluid element, the material forming the tape and its other dimensions and the size and shape of the cavity. It has been found that if the tape is rigidly attached to the housing at both ends and the tape has a relatively thin thickness dimension, automatic resetting will not occur. This has resulted in the development of various tfluid element-s employing tapes which have at least two stable states and are bistable. Such devices are disclosed and more information concerning their design and operation is contained in my co-pending patent applications Ser. Nos. 420,928 and 429,929,
  • the fluid element can be employed in a wide variety of applications, such as a logic element and/ or anact-u'ator for a mechanical device.
  • the free end portion 19 of the tape 13 is provided with an aperture 20.
  • the housing 11 has an inlet port 21 which is connected with a source of fluid under pressure 22 and an outlet port 23 leading to a fluid sensitive device, not particularly shown.
  • the aperture 20 in the movable end portion 19 of the tape is not aligned with inlet and outlet ports 21 and 23. These ports are effectively blocked and no fluid under pressure is directed to the fluid sensitive device connected to outlet port 23.
  • the aperture 20 preferably has a shape which permits the greatest fluid flow in the shortest length of d tape, such as an elongated slot extending transversely across the surface of the tape.
  • the fluid element of this invention is generally fluid tight anda minimum of leakage occurs when the tape is employed as a valving element. This is an important advantage in many applications since fluid is not continuously flowing through and being exhausted in both states of the fluid element as is the case with other fluid logic elements, such as fluid jet amplifiers. This permits the pumps or other means defining the sources of fluid under pressure to be of substantially reduced size and capacity compared to those required for use with prior art fluid logic elements when performing the same functions or accomplishing the same results.
  • the aperture 20 can be positioned so the inlet and outlet ports 21 and 23 are in communication when the fluid element is in its unactuated and stable state. In this event fluid is blocked from the fluid sensitive output device only during the transient state of the fluid element when the tape 13 is maintained in the cavity 15. More than a single pair of inlet and outlet ports can be formed in the housing and more than one valving aperture can be provided in the movable end portion of the tape as required to perform complicated valving functions, such as opening a plurality of fluid circuits while concurrently closing other fluid circuits. This makes the fluid elements of the present invention particularly useful in performing logic operations in parallel since many fluid 7 channels can be controlled by a single tape.
  • FIGURE 3 of the drawings Another monostable fluid element is shown in FIGURE 3 of the drawings.
  • This device has a plurality of transient stable states and can be employed to perform more complicated valving functions.
  • a housing has a slot 31 formed therein which slidably receives a tape 32 of strong and flexible material.
  • the tape is anchored at one end in the housing by bolt 33 and has a pair of spaced valving apertures 34 and 35 in the movable end portion of the tape.
  • the housing has a pair of generally U- shaped cavities 36 and 37 formed therein in series relation adjacent the slot 31. These cavities have the same size in that each will receive the same length of tape when the same is deflected.
  • Actuating ports 38 and 39 are provided in the housing and are connected to the inv dividually act-uatable valved sources of fluid under pressure 40 and 41. Spaced pairs of inlet and outlet ports 42 and 43 are also formed in the housing 30 and the inlet ports are connected to a source of fluid under pressure 44 while the outlet ports lead to pressure sensitive output devices, not shown.
  • FIGURES. 4 and 5 of the drawings wherein a binary to decimal converter is illustrated.
  • the converter comprises a housing 50 having spaced upper and lower walls 51 and 52.
  • the walls are provided with ten pairs of vertically aligned and spaced inlet and outlet apertures 53 and 54.
  • the outlet apertures 54 represent the ten integers of the decimal system and are connected with fluid sensitive devices, not shown, While fluid under pressure is supplied to the inlet apertures from source 55.
  • Between the upper and lower walls 51 and 52 of the housing are formed five slots 56 which receive the five tapes 57-61.
  • the tape 57 is a gating tape while tapes 58-61 correspond to the first four orders of the binary numbering system.
  • a plurality of valving and coding apertures 62 and 63, respectively, are provided in the tapes 58-61 while interconnecting passageways 64 are formed in the housing 50.
  • the over-alloperation of the binary to decimal converter is that fluid signals corresponding to the binary representations of a number to be converted are supplied to appropriate ones of the actuating ports 65-68.
  • the corresponding ones of the tapes, 58-61 are forced into their associated cavities 69-72.
  • a fluid gating signal is applied to actuating port 73 and gating tape 57 is moved due to its deflection into cavity 74.
  • the positioning of the valving 'and coding apertures 62 and 53 in the tapes is such that a fluid passageway exists between the inlet and outlet apertures 53 and 54 corresponding to the decimal equivalent of the binary fluid input signals.
  • a fluid output signal is passed to the appropriate pressure sensitive output device to complete the conversion operation.
  • FIGURE 5 of the drawings The arrangement of the valving and coding apertures 62 and 63 in the tapes 58-61 is shown schematically in FIGURE 5 of the drawings.
  • the symbol X indicates a valving aperture 62 in a tape which moves into fluid passing alignment with the associated pair of inlet and outlet apertures 53 and 54 when the tape is deflected into its cavity.
  • the symbol 0 designates a coding aperture in a tape which moves from alignment with the associated pair of inlet and outlet apertures 53 and 54 when the tape is moved to its transient state in response to an applied fluid signal.
  • the binary to decimal converter can be expanded to convert binary numbers greater than ten by the provision of more tapes, additional coding and valving apertures in the tapes and more pairs of inlet and outlet apertures. It should be clearly understood that the binary to decimal converted shown in FIGURES 4 and 5 of the drawings is intended to be representative only of a wide variety of complicated logic functions which can be accomplished when the fluid elements of this invention are employed. For example, a two dimensional switching matrix is easily fabricated where two groups of tapes with.
  • the fluid element can be used as a transducer for converting a fluid input signal into a mechanical movement which is employed to actuate a mechanical element.
  • a housing 70 is formed with an elongated slot 71. Received within the slot 71 is a rectangular tape 72 whose one end is anchored to the housing by bolt 73 while its free end portion 74 extends from the housing and is connected directly to the mechanical element to be actuated.
  • themechanical element is alatch 75 employed to hold a cycle clutch 76 of a typewriter in its unactuated condition. When the latch 75 is moved, the cycle clutch 76 is released and engages so that the typewriter is driven through a printing cycle. At the end of the cycle, the latch 75 re-engages and the apparatus is again ready to be actuated in response to a fluid input signal.
  • a cavity 77 Formed in the housing 70 adjacent the anchored end of the tape 72 is a cavity 77 whose lower end is completely open and exhausted to atmosphere.
  • the upper edges 78 of the cavity 77 are rounded or contoured to assist in the deflection of the tape into the cavity.
  • An actuating port 79 is provided in the housing at a point opposite the cavity and is in communication with a valved source of fluid under pressure 80.
  • the bottom of the cavity 77 is completely open rather than contoured as are the cavities shown inthe other embodiments of the invention since it is only necessary to move the latch 75' a predetermined distance to initiate a cycle of operation.
  • FIGURE 7 of'the' drawings A representative force-displacement curve 81 for a tape of a fluid element is depicted in FIGURE 7 of'the' drawings.
  • the force or pull exerted by the tape is greatest during its initial movement and then decreases smoothly as the displacement increases. This is particularly useful when actuating a mechanical element having a large mass and a force-displacement curve like that shown at 82, such as cycle clutch latch 75.
  • the high initial force enables the latch 75 to be accelerated rapidly from rest and as the V velocity of the latch increases the available force decreases.
  • the fluid element is a force amplifier.
  • a force F represented at 83 on the graph of FIGURE 7 of the drawing is required to deflect the tape into the cavity, a higher force is exerted by the tape until a displacement D as indicated at 84 has occurred. This is explained by the fact that large movements of the tape do not occur until it has been deflected a considerable distance into the cavity.
  • the source of fluid under pressure 80 is actuated to remove fluid under pressure from the actuating port 79, the tape 72 re turns to its initial flat condition and returns the latch 75 to its original position.
  • a spring 85 can be incorporated to assist in the return movement of the tape and thelatch.
  • fluid elements each having a single stable state which are capable of being used as actuators and of performing various and complicated logic functions.
  • the fluid elements are fast acting and character-' In the other em- 7 ized by their extreme simplicity in construction and operation. They can be manufactured at low cost using conventional plastic molding techniques and are highly reliable.
  • the devices are monostable and automatically reset themselves so that complicated resetting arrangements are not required.
  • the fluid elements are relatively fluid tight and fluid is not continuously exhausted and flowing through a logic system during stand by conditions as is the case with fluid jet amplifiers.
  • a fluid element comprising: a housing having an elongated slot therein; an elongated tape of flexible material movably received in said slot; means stationarily anchoring one end of said tape relative to said housing; at least one actuating cavity formed in said housing adjacent said slot for receiving said tape; a source of input signals; output means carried by a movable portion of said tape spaced from said cavity; and means responsive to the input signals for creating a pressure gradient extending transversely of said tape for deflecting the same into said actuating cavity and causing movement of said tape in said slot to shorten the overall effective length thereof and to move said output' means.
  • Apparatus according to claim 1 further characterized by:
  • said ouput means comprises valving means carried by a movable portion of said tape; conduit means for transferring energy disposed adjacent said movable portion of said tape; and said valving means cooperating with said conduit means when said tape is in one of its positions.
  • said output means comprises a valving aperture formed in a movable portion of said tape; a pair of inlet and outlet ports formed in said housing on opposite sides of said slot and communicating therewith; and
  • saidcource of input signals comprises a source of fluid under pressure; and said means responsive to said input signals comprises an actuating port formed in said housing and communicating with said slot adjacent to and on the opposite side of said tape from said actuating cavity.
  • a fluid element comprising: a housing having an elongated slot therein; an elongated tape of flexible material movably received in said slot;
  • actuating port in said housing communicating with said slot adajcent to and on the opposite side of said tape from said actuating cavity for creating a pressure gradient extending transversely of said tape for deflecting the same into said actuating cavity to shorten the overall effective length of said tape;
  • valving means carried by a movable portion of said tape spaced from said cavity;
  • conduit means for transferring energy disposed adjacent said movable portion of said tape
  • said valving means cooperating with said conduit means when said tape is in at least one of its positions.
  • valving means comprises a valving aperture in said movable portion of said tape spaced from said cavity;
  • said conduit means comprises a pair of inlet and outlet ports formed in said housing and communicating with said slot.
  • Apparatus according to claim 7 further characterized said means responsive to said fluid input signals comprises an exhaust port communicating with the bottom of said actuating cavity.
  • Apparatus according to claim 7 further characterized by:
  • said tape being relatively stiff and resilient
  • said tape, actuating cavity and slot being designed and formed of materials so that the tape automatically returns to its initial position from said actuating cavity when said transversely extending pressure '7 gradient is removed.
  • a fluid element comprising:
  • actuating port in said housing communicating with said slot adjacent to and on the opposite side of said tape from said actuating cavity for creating a pressure gradient extending transversely of said tape for deflecting the same into said actuating cavity to shorten the overall eflective length of said tape;
  • sensing means disposed adjacent said movable portion of said tape for detemining the presence or absence of said output means
  • said output means being in sensing relation With said sensing means When said tape is in at least one of its positions.
  • a fluid element comprising:
  • actuating cavities formed in said housing disposed adjacent said slot for receiving portions of said tape; a source of input signals associated with said cavities;
  • Apparatus according to claim 12 further characterized by:
  • Apparatus according to claim 12 further characterized by:
  • Apparatus according to claim 12 further characterized by:
  • said tape being relatively stifi and resilient; and said tape, plurality of actuating cavities and slot being designed and formed of materialsv so that said tape automatically returns from at least one of said actuating cavities when the transversely extending pressure gradient associated with said one of said actuating cavities is removed.
  • a fluid element comprising: a housing having an elongated slot therein; 'an elongated tape of flexible material movably received in said slot; means stationarily mounting one end of said tape relative to said housing; a plurality of actuating cavities formed in said housing adjacent said slot for receiving portions of said tape; a source of input signals associated with said actuating cavities; means responsive to the input signals for creating pressure gradients extending transversely of said tape for deflecting the same into selected ones of said actuating cavities and causing movement of said tape in said slot to a plurality of positions to shorten the overall effective length of said tape; valving means carried by a movable portion of said tape spaced from said cavities; conduit means for transferring energy disposed adjacent said movable portion of said tape; and said valving means cooperating With said conduit means when said tape is in at least one of said positions.
  • a fluid element comprising: a housing having an elongated slot therein; an elongated tape of flexible material movably received in said slot; means stationarily mounting one end of said tape relative to said housing; a plurality of actuating cavities formed in said housing adjacent said slot for receiving portions of said tape; a source of input signals associated with said actuating cavities; means responsive to the input signals for creating pressure gradients extending transversely of said tape for deflecting the same into selected ones of said actuating cavities and causing movement of said tape in said slot to a plurality of positions to sh rten the overall eflective length of said tape; output means carried by a movable portion of said tape spaced from said cavities; sensing means disposed adjacent said movable portion of said tape for determining the presence or absence of said output means; and said output means being in sensing relation with said i1 sensing means when said tape is in at least one of said positions.
  • a fluid element comprising: a housing having an elongated slot therein; an elongated tape of flexible material movably received in said slot; means stationarily mounting one end of said tape relative to said housing; a pair of actuating cavities formed in said housing adjacent said slot for receiving portions of said tape; a source of input signals associated with said actuating cavities; means responsive to the input signals for creating pressure gradients extending transversely of said tape for deflecting the same into selected ones of said pair of actuating cavities and causing movement of the tape in said slot to a pair of positions to shorten the overall eflective length of said tape; valving means carried by a movable portion of said tape spaced from said cavities; conduit means for transferring energy disposed adjacent said movable portion of said tape; and said valving means co-operating with said conduit means when said tape is in at least one of said pair of positions.
  • Apparatus according to claim 19 further, characterized by:
  • a fluid element comprising: a housing having a plurality of elongated slots therein; a plurality of elongated tapes of flexible material mov- 4 ably received in said slots;
  • Apparatus according to claim 22 further characterized by: said output means comprises valving means carried by movable portions of said tapes; conduit means for transferring energy disposed adjacent said movable portions of said tape; and said valving means permitting the transfer of energy Via said conduit means when a selected pair of said tapes are deflected into their associated actuating cavities.
  • a fluid element comprising: a plurality of elongated flexible tapes; each of said tapes being movably received in a slot; means stationarily anchoring one end of each of said tapes an actuating cavity disposed adjacent each slot for receiving a portion of the associated tape;
  • each of said tapes carrying valving means on a movable portion thereof spaced from the associated actuating cavity;
  • conduit means transferring energy in a manner corresponding to the deflection of said tapes into said actuating cavities in response to said input signals.
  • Apparatus according to claim 24 further characterized by:
  • At least one of said tapes being relatively stiff and resilient
  • said one of said tapes 'and its associated actuating cavity being designed so that this tape automatically returns from said associated actuating cavity to its initial position when said means responsive is not operative to deflect this tape.
  • a fluid element comprising:
  • Apparatus according to claim 26 further characterized by:
  • said source of input signals comprises a source of fluid under pressure
  • said means responsive to said input signals comprises an actuating port in said housing adjacent to and disposed on the opposite side of said tape from said actuating cavity.

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  • General Engineering & Computer Science (AREA)
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  • Coating Apparatus (AREA)

Description

April 4, 1967 w. F. von, JR 3,312,238
MONOSTABLE FLUID LOGIC ELEMENT AND ACTUATOR Filed 6 24 1964 2 sheets-sheet 1 X Q EB S 18 SOURCE OF FLUID 22 P UNDER PRESSURE UNDER PRESSURE 2 VALVED SOURCE SOURCE 0FFLU|D UNDER PRESSURE I w G. 3 N S 44 41 VALVED SOURCE- VALVED SOURCE SOURCE or FLUID 0F FLUID 0F FLUID UNDER PRESSURE UNDER PRESSURE UNDER PRESSURE R as as E l I 1 I 1 INVENTOR. I
WILLIAM F. VOIT,JR.
ATTORNEY.
w. F. VOIT, JR 3,312,238 MONOSTABLE ELUID LQGIC ELEMENT AND ACTUATOR 2 Sheets- Sheet 2 F iled Dec. 24, 1964 FIG. 4
"Huh-T T I I I 1 UNDER PRESSURE SOURCE OF FLUID SOURCE OF BINARY FLUID INPUT SIGNALS 58 DECIMAL OUTPUT FIG. 5
TAPE 58 TAPE 59 TAPE 60 TAPE 6I FIG. 6 VALVED SOURCE.
0F FLUID UNDER PRESSURE FORCE DISPLACEMENT United States fPatent Ofitice 3,312,238 Patented Apr. 4, 1967 3,312,238 MONOSTAELE FLUID LOGIC ELEMENT AND AtITUATOR William F. Voit, Jr., Lexington, Ky., assignor to International Business Machines Corporation, Armonk, N.Y.,
a corporation of New York Filed Dec. 24, 1964, Ser. No. 421,032 27 Ciaims. (til. 137-552.5)
The present invention relates generally to the logic and actuator arts and more particularly to the provision of fluid elements each having a single stable state which are capable of being used as actuators for mechanical apparatus and of performing various logic operations of the type usually accomplished by electrical components.
Recently, much interest has been evidenced in the possible use of various fluid operated elements to perform logical functions normally associated with electrical components. One such fluid element is the fluid jet amplifier wherein a stream of fluid issuing from a nozzle is directed to either of a pair of outlet ports. The fluid jet is switched between the outlet ports by appropriately directed pressure gradients applied transversely across the fluid jet between the spaced nozzle and the pair of outlet ports. The pressure gradients are provided through the use of fluid control streams, vacuums, electrical discharges or the like. The fluid jet amplifier is a bistable device in that the fluid jet will remain directed toward a particular outlet port even though the controlling transverse pressure gradient is removed due to the boundary layer condition existing between the fluid jet and the adjacent side wall of the outlet port. 1
Fluid elements of the type mentioned above are relatively fast acting, occupy a minimum of space and can be fabricated at a low cost using conventional plastic molding techniques. The fluid elements can be interconnected to perform complex logic functions and are highly reliable in the sense they do not wear out and require replacement as do conventional electrical components. While these advantages have been widely recognized, several problems have somewhat limited the use of such fluid elements. A relatively large volume source of fluid under pressure is required siiice fluid is continuously moving through the fluid jet amplifiers and exhausted during standby conditions. Also, fluid jet amplifiers are load sensitive devices and various vents must be provided adjacent the outlet ports so that such amplifiers are not capable of performing much work.
Briefly, this invention is concerned with the provision of highly improved fluid logic and actuator elements. The basic fluid element comprises a strip or tape of flexible material which is received in an elongated slot in a housing. One end portion of the tape is stationarily mounted or anchored with respect tothe housing and the other end portion of the tape is free to move in the elongated slot. A cavity is formed in the housing adjacent one side of the slot and an actuating port communicates with the slot on the opposite side of the tape from the cavity. A pressure gradient is created between the actuating port and the bottom of the cavity whereby the portion of the tape overlying the cavity is forced into the cavity and the free end portion of the tape moves in the slot in the housing. The material forming the tape, its mounting and dimensions, in combination with the dimensions and shape of the cavity, are selected so that when the pressure gradient is removed the tape returns to its original position.
cut conditions are in communication with each other or blocked depending on whether the tape is in its actuated or initial at rest condition. A plurality of tapes can be arranged in a single housing in generally overlying relation. The apertures in the tapes are positioned or coded in a manner to provide for the accomplishment of relatively complicated logic functions, such as converting signals from one code to a different code.
The fluid element of the present invention also provides a transducing means for directly actuating mechanical elements in responseto applied fluid signals. The movable free end portion of the tape is directly attached to a mechanical device to be moved. The mechanical device is actuated in response to the application of the pressure gradient across the tape which causes the same to move into the cavity in the housing.
It is the primary or ultimate object of the present invention to provide fluid elements capable of per-forming logic functions and/0r serving as actuators for directly applying actuating forces to mechanical devices. The fluid elements each comprise a strip or tape of flexible material which is movable longitudinally in a slot in a housing in response to applied fluid signals. A cavity is formed in the housing adjacent the slot and the applied fluid signal forces the tape into the cavity to cause the longitudinal movement of the tape in the slot.
Another object of invention is the provision of a fluid,
element which is monostable and returns to its initial state when the fluid actuating signal is removed. The material, size and mounting of the tape are such that the tape automatically returns from the cavity in the housing to its initial flat condition when the fluid input signal is removed.
Yet another object of the invention is to provide a fluid element that can be readily combined with other generally similar fluid elements to perform complicated logic functions. In one illustrated embodiment of the invention, a plurality of the strips or tapes are arranged The free end portion of the tape of the fluid element J in overlying relation. Apertures corresponding to logic functions to be performed are provided in the movable ends of the strips for controlling the flow of fluid between various inlet and outlet ports.
Still another object of the invention is the provision of fluid elements capable of being interconnected to perform complicated logic functions wherein relatively low volume fluid supply means are required. The fluid elements are relatively fluid tight and fluid, other than normal leakage, is not continuously exhausted during standby operations as is the case with conventional fluid jet amplifiers. a
A further object of this invention is the provision of a fluid element or transducer adapted to be directly connected to and actuate mechanical elements. The forcedisplacement curve associated with the actuator is such that a large force is available during the initial movement of the tape. This characteristic matches very closely the actuating requirements of a high mass load, such as the cycle clutch latch in a typewriter, for example.
Still a further object of the invention is to provide a logic element and/or actuator having the characteristics above described which is extremely simple in construction and operation. The elements are formed employing conventional plastic molding techniques at low cost. The fluid logic elements are highly reliable in operation and do not wear out as do analogous electrical components.
The foregoing and other objects and advantages of the invention will be apparent from the following more particular description of preferred embodiments of the invention as illustrated in the accompanying drawings.
In the drawings:
FIGURE 1 is a side sectional view showing a fluid ele- .ment constructed and operated in accordance with the .teachings of the present invention;
FIGURE 2 is a side sectional view showing the fluid element of FIGURE 1 in its actuated and transient state;
FIGURE 3 is a side sectional view of another fluid element embodying the teachings of this invention;
FIGURE 4 is a side sectional view of a decoding device illustrating the manner in Which the fluid elements :may be combined to perform complicated logic functions;
FIGURE 5 is a schematic chart in which the tapes employed in the decoding device of FIGURE 4 are laid out vin side-by-side relation to better illustrate the cooperation 'of the tapes with each other in performing the decoding function;
FIGURE 6 is a side perspective view of a fluid element illustrating its use as a fluid-to-mechanical transducer for actuating a mechanical device; and
FIGURE 7 is a graph depicting the force versus displacement relationship for the tape of a fluid element during the actuation thereof.
Referring now to the drawings, and initially to FIG- URES 1 and 2 thereof, the reference numeral '10 designates generally a fluid element embodying the teachings of this invention. The fluid element comprises a housing 11 of plastic or other similar material which is formed with an opening to provide a generally thin and rectangular elongated slot 12. Received within the slot 1 2 is a flexible rectangular strip or tape 13 of plastic or metal, such as Mylar or strip steel for example. The tape 13,is anchored to the housing 11 at one end by bolt '14 or any other convenient means and its other end is free to move in the slot 12.
Formed in the housing 11 adjacent the anchored end of the tape 13 is a generally U-shaped cavity which communicates with the slot 12. The bottom of the cavity 15 is exhausted to atmosphere by a pair of exhaust ports 16. Provided in the housing 11 on the opposite side of the slot 12 and tape 13 from the cavity 15 is an actuating port 17 which is in communication with a valved source of fluid under pressure represented schematically at 18 in the drawings.
When fluid pressure is applied to actuating port 17, a force is exerted on the surface of tape 13 adjacent the actuating port and a pressure gradient exists in a direction extending transversely of the tape. This pressure gradient immediately causes the tape to be deflected into and conform to the shape of the cavity 15 as is clearly shown in FIGURE 2 of the drawings. The cavity 15 has approximately the same width dimension as that of the portion of the tape 13 received within the cavity so that fluid leakage is maintained at a minimum during and does not markedly effect the speed of operation of the device. The free end portion 19 of the tape 13 moves through a linear distance correspondingdirectly to the length of tape required to conform to the bottom contour of the cavity 15. The exhaust ports. 16 prevent the entrapment of fluid and the build up of fluid pressure between the bottom of the cavity 15 and the tape 13 so that the tape moves very quickly and smoothly into the cavity.
The movement of the tape 13 into the cavity 15 is caused by a pressure gradient which extends transversely of the tape as explained above. It should be understood at the outset that the pressure gradient can be created I in various ways, including applying a fluid input pulse to one side of the tape 13 while exhausting the cavity 15 as employed in connection with the illustrated embodiments of the invention. Alternately, the exhaust ports 16 can be normally blocked and fluid under pressure always supplied to the actuating port 17. A condition of pressure equilibrium would then exist because of the nominal clearance between the edges of the tape and the cavity. The tape 13 would remain in its unactuated state until the exhaust ports 16 are opened to create the tape deflecting pressure gradient. Still another manner of providing the pressure gradient extending transversely of the tape 13 to deflect the same into the cavity is to apply vacuum to the exhaust ports 16.
A highly important aspect of this invention is that the fluid element is a monostable device since it has a single stable state (the unactuated or initial state shown in FIGURE 1 of the drawings) and a transient unstable state (the actuated state shown in FIGURE 2 of the drawings) which exists only as long as an actuating pressure gradient extends transversely of the tape 13 to hold the same deflected in the cavity 15. As soon as the source of fluid under pressure 18 is eflectively disconnected from the actuating port 17, the tape 13 automatically returns to its initial and flat condition without external assistance of any kind.
Experiments have shown that if the fluid element is properly designed and the tape correctly mounted, there is suflicient energy stored in the deformed portion of the tape tending to straighten the tape which overcomes its mass, the frictional forces acting thereon and any other fluid forces acting thereon when the free end portion of the tape is used as a valving element. In several successfully operating constructed embodiments of the in vention, the tape employed was a piece of Mylar plastic having a thickness of three mils and a width of .312 of an inch. The cavity was approximately .80 of an inch long and .165 of an inch deep at its deepest point. The thickness of the tape is selected so that the time required for the tape to automatically return to its initial and stable state is approximately the same as the time required to deflect the tape into the cavity. As a general rule, when the thickness is increased, the resetting action occurs at a faster'rate. Thus, the design of the thickness of the tape provides a means for controlling the automatic re-- setting of the fluid element. Fluid elements'having the dimensions set forth above are actuated and automatically reset within time intervals in the range of three to six milliseconds.
Critical aspects of the design of a fluid element are the thickness dimension and mounting of the tape considering the use projected for the fluid element, the material forming the tape and its other dimensions and the size and shape of the cavity. It has been found that if the tape is rigidly attached to the housing at both ends and the tape has a relatively thin thickness dimension, automatic resetting will not occur. This has resulted in the development of various tfluid element-s employing tapes which have at least two stable states and are bistable. Such devices are disclosed and more information concerning their design and operation is contained in my co-pending patent applications Ser. Nos. 420,928 and 429,929,
entitled Bistable Fluid Logic Element and Fluid Display and Converter Device, both filed concurrently with this application and both assigned to the assignee of the present invention. The latter application issued as Patent No. 3,263,922 on Aug. 2, 1966.
The fluid element can be employed in a wide variety of applications, such as a logic element and/ or anact-u'ator for a mechanical device. The free end portion 19 of the tape 13 is provided with an aperture 20. Also, the housing 11 has an inlet port 21 which is connected with a source of fluid under pressure 22 and an outlet port 23 leading to a fluid sensitive device, not particularly shown. When the fluid device is in its unactuated and stable state, the aperture 20 in the movable end portion 19 of the tape is not aligned with inlet and outlet ports 21 and 23. These ports are effectively blocked and no fluid under pressure is directed to the fluid sensitive device connected to outlet port 23. However, when the valved source of fluid under pressure 18 is actuated and the tape 13 is forced into the cavity 15, the aperture 20 in the free end portion of the tape move into alignment with inlet and outlet ports 21 and 23. Fluid under pressure is supplied to the fluid sensitive device as is illustrated in FIGURE 2 of the drawings. The aperture 20 preferably has a shape which permits the greatest fluid flow in the shortest length of d tape, such as an elongated slot extending transversely across the surface of the tape. H
Experiments have shown that the fluid element of this invention is generally fluid tight anda minimum of leakage occurs when the tape is employed as a valving element. This is an important advantage in many applications since fluid is not continuously flowing through and being exhausted in both states of the fluid element as is the case with other fluid logic elements, such as fluid jet amplifiers. This permits the pumps or other means defining the sources of fluid under pressure to be of substantially reduced size and capacity compared to those required for use with prior art fluid logic elements when performing the same functions or accomplishing the same results.
It should be apparent that the use of the movable end portion 19 of the tape 13 as a valving member can take various forms. The aperture 20 can be positioned so the inlet and outlet ports 21 and 23 are in communication when the fluid element is in its unactuated and stable state. In this event fluid is blocked from the fluid sensitive output device only during the transient state of the fluid element when the tape 13 is maintained in the cavity 15. More than a single pair of inlet and outlet ports can be formed in the housing and more than one valving aperture can be provided in the movable end portion of the tape as required to perform complicated valving functions, such as opening a plurality of fluid circuits while concurrently closing other fluid circuits. This makes the fluid elements of the present invention particularly useful in performing logic operations in parallel since many fluid 7 channels can be controlled by a single tape.
Another monostable fluid element is shown in FIGURE 3 of the drawings. This device has a plurality of transient stable states and can be employed to perform more complicated valving functions. A housing has a slot 31 formed therein which slidably receives a tape 32 of strong and flexible material. The tape is anchored at one end in the housing by bolt 33 and has a pair of spaced valving apertures 34 and 35 in the movable end portion of the tape. The housing has a pair of generally U- shaped cavities 36 and 37 formed therein in series relation adjacent the slot 31. These cavities have the same size in that each will receive the same length of tape when the same is deflected. Actuating ports 38 and 39 are provided in the housing and are connected to the inv dividually act-uatable valved sources of fluid under pressure 40 and 41. Spaced pairs of inlet and outlet ports 42 and 43 are also formed in the housing 30 and the inlet ports are connected to a source of fluid under pressure 44 while the outlet ports lead to pressure sensitive output devices, not shown.
In the unactuated and stable state of the fluid element as shown in FIGURE 3 of the drawings, the apertures 34 and 35 are not aligned with pairs of inlet and outlet ports 42 and 43. If fluid under pressure is applied to either of the actuatingports 38 or 39, the tape 32is forced into the corresponding one of the cavities 36 or 37 and theaperture 34 in the movable end of the tape moves into alignment with the pair of ports 42. At this time the tape 32 has not moved sufliciently to cause aperture 35 to become aligned with the pair of inlet and outlet ports 43 and these ports remain blocked. This operation corresponds to the logical exclusive OR function in that either of two inputs, but not both, will provide a particular type of output. If at any time fluid under pressure is simultaneously applied to the actuating ports 38 and 39, the tape 32 is moved into both of the cavities 3-6 and 37 so that the aperture 34 moves to the left past the pair of ports 42 while the aperture 35 moves into aligned relation with the pair of ports 43. This defines a second transient state which provides an output when all of a number' of input signals are present and corresponds generally to the logical AND condition. Regardless of the combination of fluid input signals applied to the input ports 38 and 39 -and the type of output signals produced, the tape 32 returns to its initial flat condition and'the fluid element is in its unactuated stable state when all of the input signals are removed as is the condition represented in FIGURE 3 of the drawings. While a series of two cavities 36 and 37 have been described in connection with this embodiment of the invention, it should be understood that three or more cavities could be employed depending on the results required for any given application.
-Any number of the basic fluid elements described above can be'comb-ined in almost unlimited fashion to perform complicated logic functions. An example of this is shown in FIGURES. 4 and 5 of the drawings wherein a binary to decimal converter is illustrated. The converter comprises a housing 50 having spaced upper and lower walls 51 and 52. The walls are provided with ten pairs of vertically aligned and spaced inlet and outlet apertures 53 and 54. The outlet apertures 54 represent the ten integers of the decimal system and are connected with fluid sensitive devices, not shown, While fluid under pressure is supplied to the inlet apertures from source 55. Between the upper and lower walls 51 and 52 of the housing are formed five slots 56 which receive the five tapes 57-61. The tape 57 is a gating tape while tapes 58-61 correspond to the first four orders of the binary numbering system. A plurality of valving and coding apertures 62 and 63, respectively, are provided in the tapes 58-61 while interconnecting passageways 64 are formed in the housing 50.
The over-alloperation of the binary to decimal converter is that fluid signals corresponding to the binary representations of a number to be converted are supplied to appropriate ones of the actuating ports 65-68. The corresponding ones of the tapes, 58-61 are forced into their associated cavities 69-72. After the selected binary tapes have been set, a fluid gating signal is applied to actuating port 73 and gating tape 57 is moved due to its deflection into cavity 74. The positioning of the valving 'and coding apertures 62 and 53 in the tapes is such that a fluid passageway exists between the inlet and outlet apertures 53 and 54 corresponding to the decimal equivalent of the binary fluid input signals. A fluid output signal is passed to the appropriate pressure sensitive output device to complete the conversion operation. When the gating and binary fluid input signals are removed from the selected actuating ports 65-68 and 73, the tapes 57-61 automatically return to their initial unactuated states without-the use of resetting means of any kind.
- The arrangement of the valving and coding apertures 62 and 63 in the tapes 58-61 is shown schematically in FIGURE 5 of the drawings. The symbol X indicates a valving aperture 62 in a tape which moves into fluid passing alignment with the associated pair of inlet and outlet apertures 53 and 54 when the tape is deflected into its cavity. The symbol 0 designates a coding aperture in a tape which moves from alignment with the associated pair of inlet and outlet apertures 53 and 54 when the tape is moved to its transient state in response to an applied fluid signal. For those desiring a complete description of the mathematical basis of the positioning of the valving and codingapertures 62 and 63 in the tapes, reference is made to US. Patent 2,904,070, issued Sept. 15, 1959, entitled, .Multi-Port Selector, and assigned to the assignee of this invention. The binary to decimal converter can be expanded to convert binary numbers greater than ten by the provision of more tapes, additional coding and valving apertures in the tapes and more pairs of inlet and outlet apertures. It should be clearly understood that the binary to decimal converted shown in FIGURES 4 and 5 of the drawings is intended to be representative only of a wide variety of complicated logic functions which can be accomplished when the fluid elements of this invention are employed. For example, a two dimensional switching matrix is easily fabricated where two groups of tapes with.
appropriate valving apertures therein are disposed in overlying relation at right angles with respect to each other. Coincident energization or deflection of a tape from each of the tape groups is required to obtain an output fluid pulse as will be understood by those skilled in the art.
The fluid element can be used as a transducer for converting a fluid input signal into a mechanical movement which is employed to actuate a mechanical element. This is shown in FIGURE 6 of the drawings where a housing 70 is formed with an elongated slot 71. Received within the slot 71 is a rectangular tape 72 whose one end is anchored to the housing by bolt 73 while its free end portion 74 extends from the housing and is connected directly to the mechanical element to be actuated. In the illustrated embodiment, themechanical element is alatch 75 employed to hold a cycle clutch 76 of a typewriter in its unactuated condition. When the latch 75 is moved, the cycle clutch 76 is released and engages so that the typewriter is driven through a printing cycle. At the end of the cycle, the latch 75 re-engages and the apparatus is again ready to be actuated in response to a fluid input signal.
Formed in the housing 70 adjacent the anchored end of the tape 72 is a cavity 77 whose lower end is completely open and exhausted to atmosphere. The upper edges 78 of the cavity 77 are rounded or contoured to assist in the deflection of the tape into the cavity. An actuating port 79 is provided in the housing at a point opposite the cavity and is in communication with a valved source of fluid under pressure 80. The bottom of the cavity 77 is completely open rather than contoured as are the cavities shown inthe other embodiments of the invention since it is only necessary to move the latch 75' a predetermined distance to initiate a cycle of operation. bodiments Where coding and valving apertures are provided inthe free end portions of the tapes, it is desirable to accurately control the extent of movement of the tapes in order that the valving operations are properly performed. The rounded upper edges of the cavities employed in all of the examples have been found to be of particular value and assistance in causing the tapes to quickly move into the cavities in a smooth manner when fluid actuating signals are applied.
A representative force-displacement curve 81 for a tape of a fluid element is depicted in FIGURE 7 of'the' drawings. The force or pull exerted by the tape is greatest during its initial movement and then decreases smoothly as the displacement increases. This is particularly useful when actuating a mechanical element having a large mass and a force-displacement curve like that shown at 82, such as cycle clutch latch 75. The high initial force enables the latch 75 to be accelerated rapidly from rest and as the V velocity of the latch increases the available force decreases.
More force is available forum: in actuating a mechanical element than is required to operate or move the tape initially and in this sense the fluid element isa force amplifier. For example, if a force F represented at 83 on the graph of FIGURE 7 of the drawing is required to deflect the tape into the cavity, a higher force is exerted by the tape until a displacement D as indicated at 84 has occurred. This is explained by the fact that large movements of the tape do not occur until it has been deflected a considerable distance into the cavity. When the source of fluid under pressure 80 is actuated to remove fluid under pressure from the actuating port 79, the tape 72 re turns to its initial flat condition and returns the latch 75 to its original position. If desired, a spring 85 can be incorporated to assist in the return movement of the tape and thelatch.
It should now be apparent that the objects initially set forth have been accomplished. Of particular importance is the provision of fluid elements each having a single stable state which are capable of being used as actuators and of performing various and complicated logic functions. The fluid elements are fast acting and character-' In the other em- 7 ized by their extreme simplicity in construction and operation. They can be manufactured at low cost using conventional plastic molding techniques and are highly reliable. The devices are monostable and automatically reset themselves so that complicated resetting arrangements are not required. Further, the fluid elements are relatively fluid tight and fluid is not continuously exhausted and flowing through a logic system during stand by conditions as is the case with fluid jet amplifiers.
While the invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that the foregoing and other changes in form and details may be made therein without departing from the spirit and scope of the invention.
What is claimed is: 1. A fluid element comprising: a housing having an elongated slot therein; an elongated tape of flexible material movably received in said slot; means stationarily anchoring one end of said tape relative to said housing; at least one actuating cavity formed in said housing adjacent said slot for receiving said tape; a source of input signals; output means carried by a movable portion of said tape spaced from said cavity; and means responsive to the input signals for creating a pressure gradient extending transversely of said tape for deflecting the same into said actuating cavity and causing movement of said tape in said slot to shorten the overall effective length thereof and to move said output' means. 2. Apparatus according to claim 1 further characterized by:
said tape being relatively stiff and resilient; and said tape, actuating cavity and slot being designed and formed of materials'so that said tape automatically returns to its initial position from said actuating cavity when said transversely extending pressure gradient is removed. 3. Apparatus according to claim 1 further characterized by:
said ouput means comprises valving means carried by a movable portion of said tape; conduit means for transferring energy disposed adjacent said movable portion of said tape; and said valving means cooperating with said conduit means when said tape is in one of its positions. 4. Apparatus according to claim 1 further characterized by:
said output means comprises a valving aperture formed in a movable portion of said tape; a pair of inlet and outlet ports formed in said housing on opposite sides of said slot and communicating therewith; and
said valving aperture interconnecting said pair of inlet and outlet ports when said tape is in one of its positions. 5. Apparatus according to. claim 1 further characterized by:
saidcource of input signals comprises a source of fluid under pressure; and said means responsive to said input signals comprises an actuating port formed in said housing and communicating with said slot adjacent to and on the opposite side of said tape from said actuating cavity. 6. Apparatus according to claim 1 further characterized by:
said actuating cavity being U-shaped in cross sectional shape. 7. A fluid element comprising: a housing having an elongated slot therein; an elongated tape of flexible material movably received in said slot;
means stationarily anchoring one end of said tape relative to said housing;
an actuating cavity formed in said housing adjacent said means for anchoring and communicating with said slot;
a source of fluid input signals;
means responsive to said fluid input signals comprising an actuating port in said housing communicating with said slot adajcent to and on the opposite side of said tape from said actuating cavity for creating a pressure gradient extending transversely of said tape for deflecting the same into said actuating cavity to shorten the overall effective length of said tape;
valving means carried by a movable portion of said tape spaced from said cavity;
conduit means for transferring energy disposed adjacent said movable portion of said tape; and
said valving means cooperating with said conduit means when said tape is in at least one of its positions.
8. Apparatus according to claim 7 further characterized said valving means comprises a valving aperture in said movable portion of said tape spaced from said cavity; and
said conduit means comprises a pair of inlet and outlet ports formed in said housing and communicating with said slot.
9. Apparatus according to claim 7 further characterized said means responsive to said fluid input signals comprises an exhaust port communicating with the bottom of said actuating cavity.
10. Apparatus according to claim 7 further characterized by:
said tape being relatively stiff and resilient; and
said tape, actuating cavity and slot being designed and formed of materials so that the tape automatically returns to its initial position from said actuating cavity when said transversely extending pressure '7 gradient is removed.
11. A fluid element comprising:
a housing having an elongated slot therein;
an elongated tape of flexible material rnovably received in said slot;
means stationarily anchoring one end of said tape relative to said housing; I
an actuating cavity formed in said housing adjacent said means for anchoring and communicating with said slot;
a source of fluid input. signals;
means responsive to said fluid input signals comprising an actuating port in said housing communicating with said slot adjacent to and on the opposite side of said tape from said actuating cavity for creating a pressure gradient extending transversely of said tape for deflecting the same into said actuating cavity to shorten the overall eflective length of said tape;
output means carried by a movable portion of said tape spaced from said cavity;
sensing means disposed adjacent said movable portion of said tape for detemining the presence or absence of said output means;
said output means being in sensing relation With said sensing means When said tape is in at least one of its positions.
12. A fluid element comprising:
a housing having an elongated slot therein;
an elongated tape of flexible material movably received in said slot;
means stationarily anchoring one end of said tape relative to said housing;
- a plurality of actuating cavities formed in said housing disposed adjacent said slot for receiving portions of said tape; a source of input signals associated with said cavities;
output means carried by a movable portion of said tape spaced from said cavity; and means responsive to the input signals for creating pressure gradients extending transversely of said tape for deflecting the same into selected ones of said actuating cavities and causing movement of said tape in said slot to shorten the overall effective length of said tape and to move said output means. 13. Apparatus according to claim 12 further characterized by:
said plurality of actuating cavities being positioned adjacent said means for anchoring in longitudinally aligned series relation along said slot. 14. Apparatus according to claim 12 further characterized by:
at least tWo of said plurality actuating cavities being the same size. 15. Apparatus according to claim 12 further characterized by:
all of said plurality of actuating cavities being the same size. 16. Apparatus according to claim 12 further characterized by;
said tape being relatively stifi and resilient; and said tape, plurality of actuating cavities and slot being designed and formed of materialsv so that said tape automatically returns from at least one of said actuating cavities when the transversely extending pressure gradient associated with said one of said actuating cavities is removed. 17. A fluid element comprising: a housing having an elongated slot therein; 'an elongated tape of flexible material movably received in said slot; means stationarily mounting one end of said tape relative to said housing; a plurality of actuating cavities formed in said housing adjacent said slot for receiving portions of said tape; a source of input signals associated with said actuating cavities; means responsive to the input signals for creating pressure gradients extending transversely of said tape for deflecting the same into selected ones of said actuating cavities and causing movement of said tape in said slot to a plurality of positions to shorten the overall effective length of said tape; valving means carried by a movable portion of said tape spaced from said cavities; conduit means for transferring energy disposed adjacent said movable portion of said tape; and said valving means cooperating With said conduit means when said tape is in at least one of said positions. 18. A fluid element comprising: a housing having an elongated slot therein; an elongated tape of flexible material movably received in said slot; means stationarily mounting one end of said tape relative to said housing; a plurality of actuating cavities formed in said housing adjacent said slot for receiving portions of said tape; a source of input signals associated with said actuating cavities; means responsive to the input signals for creating pressure gradients extending transversely of said tape for deflecting the same into selected ones of said actuating cavities and causing movement of said tape in said slot to a plurality of positions to sh rten the overall eflective length of said tape; output means carried by a movable portion of said tape spaced from said cavities; sensing means disposed adjacent said movable portion of said tape for determining the presence or absence of said output means; and said output means being in sensing relation with said i1 sensing means when said tape is in at least one of said positions. 19. A fluid element comprising: a housing having an elongated slot therein; an elongated tape of flexible material movably received in said slot; means stationarily mounting one end of said tape relative to said housing; a pair of actuating cavities formed in said housing adjacent said slot for receiving portions of said tape; a source of input signals associated with said actuating cavities; means responsive to the input signals for creating pressure gradients extending transversely of said tape for deflecting the same into selected ones of said pair of actuating cavities and causing movement of the tape in said slot to a pair of positions to shorten the overall eflective length of said tape; valving means carried by a movable portion of said tape spaced from said cavities; conduit means for transferring energy disposed adjacent said movable portion of said tape; and said valving means co-operating with said conduit means when said tape is in at least one of said pair of positions. 20. Apparatus according to claim 19 further, characterized by:
said valving means co-operating with said conduit means when said tape is deflected in either but not both of said pair of actuating cavities. 21. Apparatus according to claim 19 further characterized by:
said valving means cooperating with said conduit means when said tape is deflected into both of said pair of actuating cavities. 22. A fluid element comprising: a housing having a plurality of elongated slots therein; a plurality of elongated tapes of flexible material mov- 4 ably received in said slots;
means stationarily anchoring one end of each of said tapes relative to said housing; at least one actuating cavity formed in said housing and disposed adjacent each of said slots for receiving a portion of the associated tape to shorten theoverall eflective length of said associated tape; a source of input signals; output means carried by a movable portion of each of said tapes spaced from the actuating cavity associated therewith; and means responsive to the input signals for creating pressure gradients extending transversely of said tapes for deflecting selected ones of said tapes into their associated actuating cavities to move the corresponding ones-of said output means. 23. Apparatus according to claim 22 further characterized by: said output means comprises valving means carried by movable portions of said tapes; conduit means for transferring energy disposed adjacent said movable portions of said tape; and said valving means permitting the transfer of energy Via said conduit means when a selected pair of said tapes are deflected into their associated actuating cavities. 24. A fluid element comprising: a plurality of elongated flexible tapes; each of said tapes being movably received in a slot; means stationarily anchoring one end of each of said tapes an actuating cavity disposed adjacent each slot for receiving a portion of the associated tape;
a source of input signals;
means responsive to the input signals for deflecting selected ones of said tapes into their associated actuating cavities to shorten the overall eflective lengths of said selected ones of said tapes;
each of said tapes carrying valving means on a movable portion thereof spaced from the associated actuating cavity;
a plurality of conduit means for transferring energy disposed adjacent the movable portions of said tapes; and
said conduit means transferring energy in a manner corresponding to the deflection of said tapes into said actuating cavities in response to said input signals.
25. Apparatus according to claim 24 further characterized by:
at least one of said tapes being relatively stiff and resilient; and
said one of said tapes 'and its associated actuating cavity being designed so that this tape automatically returns from said associated actuating cavity to its initial position when said means responsive is not operative to deflect this tape.
26. A fluid element comprising:
a housing having an elongated slot therein;
an elongated tape of flexible material movably received in said slot; 7
means stationarily anchoring one end of said tape relative to said housing;
an actuating cavity formed in said housing adjacent said slot for receivingportions of said tape;
a mechanical element to be moved;
means for connecting the other end of said tape to said mechanical element;
a source of input signals; and
means responsive to the input signals for creating a pressure gradient extending transversely of said tape for deflecting the same into said actuating cavity and causing movement of said tape in said slot to shorten the overall effective length of said tape and movement of said mechanical element.
27. Apparatus according to claim 26 further characterized by:
said source of input signals comprises a source of fluid under pressure; and
said means responsive to said input signals comprises an actuating port in said housing adjacent to and disposed on the opposite side of said tape from said actuating cavity.
References Cited by the Applicant UNITED STATES PATENTS 489,193 1/1893 Mills.
760,595 5/ 1904 Wiesebrock. 2,892,379 6/1959 Cooper. 2,904,070 9/ 1959 Lynott. 3,057,375 10/1962 Etter.
3,156,157 11/1964 Smith et al.
FOREIGN PATENTS 1,085,597 1/1961 Germany.
M. CARY NELSON, Primary Examiner.
H. KLlNKSEIIQ Assistant Examiner,

Claims (1)

1. A FLUID ELEMENT COMPRISING: A HOUSING HAVING AN ELONGATED SLOT THEREIN; AN ELONGATED TAPE OF FLEXIBLE MATERIAL MOVABLY RECEIVED IN SAID SLOT; MEANS STATIONARILY ANCHORING ONE END OF SAID TAPE RELATIVE TO SAID HOUSING; AT LEAST ONE ACTUATING CAVITY FORMED IN SAID HOUSING ADJACENT SAID SLOT FOR RECEIVING SAID TAPE; A SOURCE OF INPUT SIGNALS;
US421032A 1964-12-24 1964-12-24 Monostable fluid logic element and actuator Expired - Lifetime US3312238A (en)

Priority Applications (9)

Application Number Priority Date Filing Date Title
US421032A US3312238A (en) 1964-12-24 1964-12-24 Monostable fluid logic element and actuator
GB4737365A GB1080109A (en) 1964-12-24 1965-11-09 Elements employing flexible strips for performing digital operations
DE1965J0029417 DE1296916B (en) 1964-12-24 1965-11-19 Slide valve with a valve slide that releases one or more passage openings
DE19651774810 DE1774810B1 (en) 1964-12-24 1965-11-19 FLUID CONTROLLED ACTUATING DEVICE
DE19651523540 DE1523540C (en) 1964-12-24 1965-11-29 Pneumatic or hydraulic control device for displaying and / or translating coded data
FR41674A FR1469011A (en) 1964-12-24 1965-12-10 logical element and active fluid monostable system
FR41670A FR1457217A (en) 1964-12-24 1965-12-10
NL6516771A NL149573B (en) 1964-12-24 1965-12-22 FLUIDUM-CONTROLLED SWITCHING, TRANSFER OR DISPLAY ELEMENT WITH A STRIP OF FLEXIBLE MATERIAL AS A MOVING PART.
CH1780065A CH438800A (en) 1964-12-24 1965-12-23 Pneumatic or hydraulic control device

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US421032A US3312238A (en) 1964-12-24 1964-12-24 Monostable fluid logic element and actuator

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FR (1) FR1469011A (en)

Cited By (23)

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US3442447A (en) * 1967-03-06 1969-05-06 Bowles Eng Corp Fluid signal code converter
US3521801A (en) * 1968-04-09 1970-07-28 Itt Punched tape drive and control system
US3521670A (en) * 1967-10-25 1970-07-28 Rosemount Eng Co Ltd Digitizers for fluid logic systems
US3593734A (en) * 1969-10-30 1971-07-20 Foxboro Co Pressure-responsive element
US3696977A (en) * 1971-04-21 1972-10-10 Johnson & Son Inc S C Stretch elastomer valve
US3708047A (en) * 1970-01-20 1973-01-02 Zahnradfabrik Friedrichshafen Electro-hydraulic selector for the control of multiple loads
US3717172A (en) * 1970-12-16 1973-02-20 Ibm Fluidic information storage cell
US3805939A (en) * 1971-12-02 1974-04-23 L Ross Keyboard actuator
US4621655A (en) * 1985-03-04 1986-11-11 Hydril Company Marine riser fill-up valve
US5052440A (en) * 1989-04-27 1991-10-01 Grumman Aerospace Corporation Liquid droplet generator valve
US5083742A (en) * 1990-08-01 1992-01-28 Photovac Incorporated Fluid control valve
US5197192A (en) * 1990-08-01 1993-03-30 Photovac Incorporated Method of making a fluid control valve
US5496009A (en) * 1994-10-07 1996-03-05 Bayer Corporation Valve
US5660370A (en) * 1996-03-07 1997-08-26 Integrated Fludics, Inc. Valve with flexible sheet member and two port non-flexing backer member
US5765729A (en) * 1996-02-08 1998-06-16 Liquid Control Corporation Dispenser for flowable materials
US5775371A (en) * 1995-03-08 1998-07-07 Abbott Laboratories Valve control
US5967163A (en) * 1996-01-30 1999-10-19 Abbott Laboratories Actuator and method
US6196521B1 (en) 1998-08-18 2001-03-06 Precision Valve & Automation, Inc. Fluid dispensing valve and method
US6374860B2 (en) * 1998-10-16 2002-04-23 Daniel Industries, Inc. Integrated valve design for gas chromatograph
US20070095413A1 (en) * 2005-11-01 2007-05-03 Georgia Tech Research Corporation Systems and methods for controlling the flow of a fluidic medium
US20070240496A1 (en) * 1999-02-20 2007-10-18 Bayer Healthcare Llc Variable Rate Particle Counter and Method of Use
US20080029169A1 (en) * 2002-09-25 2008-02-07 California Institute Of Technology Microfluidic large scale integration
US20120241034A1 (en) * 2008-08-20 2012-09-27 Andrew Paul Wilke Valve block assembly

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US489193A (en) * 1893-01-03 mills
US760595A (en) * 1903-08-27 1904-05-24 Frederick William A Wiesebrock Cut-off apparatus for gas or liquid supply pipes.
US2892379A (en) * 1955-04-20 1959-06-30 Robert H Cooper Pneumatic film transport
US2904070A (en) * 1955-06-06 1959-09-15 Ibm Multi-port selector
DE1085597B (en) * 1959-09-11 1960-07-21 Rueti Ag Maschf Device for controlling work processes on work machines
US3057375A (en) * 1957-07-29 1962-10-09 Trg Inc Fluid-pressure data storage device
US3156157A (en) * 1961-04-11 1964-11-10 Burroughs Corp Positioning control system and apparatus

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US489193A (en) * 1893-01-03 mills
US760595A (en) * 1903-08-27 1904-05-24 Frederick William A Wiesebrock Cut-off apparatus for gas or liquid supply pipes.
US2892379A (en) * 1955-04-20 1959-06-30 Robert H Cooper Pneumatic film transport
US2904070A (en) * 1955-06-06 1959-09-15 Ibm Multi-port selector
US3057375A (en) * 1957-07-29 1962-10-09 Trg Inc Fluid-pressure data storage device
DE1085597B (en) * 1959-09-11 1960-07-21 Rueti Ag Maschf Device for controlling work processes on work machines
US3156157A (en) * 1961-04-11 1964-11-10 Burroughs Corp Positioning control system and apparatus

Cited By (28)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3442447A (en) * 1967-03-06 1969-05-06 Bowles Eng Corp Fluid signal code converter
US3521670A (en) * 1967-10-25 1970-07-28 Rosemount Eng Co Ltd Digitizers for fluid logic systems
US3521801A (en) * 1968-04-09 1970-07-28 Itt Punched tape drive and control system
US3593734A (en) * 1969-10-30 1971-07-20 Foxboro Co Pressure-responsive element
US3708047A (en) * 1970-01-20 1973-01-02 Zahnradfabrik Friedrichshafen Electro-hydraulic selector for the control of multiple loads
US3717172A (en) * 1970-12-16 1973-02-20 Ibm Fluidic information storage cell
US3696977A (en) * 1971-04-21 1972-10-10 Johnson & Son Inc S C Stretch elastomer valve
US3805939A (en) * 1971-12-02 1974-04-23 L Ross Keyboard actuator
US4621655A (en) * 1985-03-04 1986-11-11 Hydril Company Marine riser fill-up valve
US5052440A (en) * 1989-04-27 1991-10-01 Grumman Aerospace Corporation Liquid droplet generator valve
US5083742A (en) * 1990-08-01 1992-01-28 Photovac Incorporated Fluid control valve
US5197192A (en) * 1990-08-01 1993-03-30 Photovac Incorporated Method of making a fluid control valve
US5496009A (en) * 1994-10-07 1996-03-05 Bayer Corporation Valve
US5794641A (en) * 1995-03-08 1998-08-18 Abbott Laboratories Valve control
US5775371A (en) * 1995-03-08 1998-07-07 Abbott Laboratories Valve control
US5791375A (en) * 1995-03-08 1998-08-11 Abbott Laboratories Valve control
US5967163A (en) * 1996-01-30 1999-10-19 Abbott Laboratories Actuator and method
US5765729A (en) * 1996-02-08 1998-06-16 Liquid Control Corporation Dispenser for flowable materials
US5660370A (en) * 1996-03-07 1997-08-26 Integrated Fludics, Inc. Valve with flexible sheet member and two port non-flexing backer member
US6196521B1 (en) 1998-08-18 2001-03-06 Precision Valve & Automation, Inc. Fluid dispensing valve and method
US6374860B2 (en) * 1998-10-16 2002-04-23 Daniel Industries, Inc. Integrated valve design for gas chromatograph
US20070240496A1 (en) * 1999-02-20 2007-10-18 Bayer Healthcare Llc Variable Rate Particle Counter and Method of Use
US20080029169A1 (en) * 2002-09-25 2008-02-07 California Institute Of Technology Microfluidic large scale integration
US9714443B2 (en) 2002-09-25 2017-07-25 California Institute Of Technology Microfabricated structure having parallel and orthogonal flow channels controlled by row and column multiplexors
US20070095413A1 (en) * 2005-11-01 2007-05-03 Georgia Tech Research Corporation Systems and methods for controlling the flow of a fluidic medium
US20120241034A1 (en) * 2008-08-20 2012-09-27 Andrew Paul Wilke Valve block assembly
US8590567B2 (en) * 2008-08-20 2013-11-26 Semba Biosciences, Inc. Valve block assembly
US9068662B2 (en) 2008-08-20 2015-06-30 Semba Biosciences, Inc. Valve block assembly

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