US3490477A - Rotated pattern fluidic element - Google Patents

Rotated pattern fluidic element Download PDF

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Publication number
US3490477A
US3490477A US661605A US3490477DA US3490477A US 3490477 A US3490477 A US 3490477A US 661605 A US661605 A US 661605A US 3490477D A US3490477D A US 3490477DA US 3490477 A US3490477 A US 3490477A
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Prior art keywords
chamber
flow
control
supply
pressure
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Expired - Lifetime
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US661605A
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English (en)
Inventor
Frederick D Ezekiel
Richard W Hatch Jr
Hans-Dieter Kinner
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Schneider Electric Systems USA Inc
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Foxboro Co
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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
    • F15C1/00Circuit elements having no moving parts
    • F15C1/18Turbulence devices, i.e. devices in which a controlling stream will cause a laminar flow to become turbulent ; Diffusion amplifiers
    • 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
    • Y10T137/206Flow affected by fluid contact, energy field or coanda effect [e.g., pure fluid device or system]
    • Y10T137/2087Means to cause rotational flow of fluid [e.g., vortex generator]
    • Y10T137/2109By tangential input to axial output [e.g., vortex amplifier]

Definitions

  • FIG 4 HANS-DIETER KINNER FREDERICK D- EZEKIEL BY RICHARD W. HATCH JR.
  • a fiuidic element having a supply conduit communicating with a chamber, a control conduit communicating with said chamber with a direction adapted to impart axial rotation to fluid issuing from said supply circuit, and a receiver conduit aligned with said supply conduit on a common central axis, exhibits a state wherein fluid issuing from said supply conduit and chamber combination maintains a laminar flow pattern impressing a high pressure level at said receiver conduit; this state may be altered by control flow through said control conduit which operates to torque the supply flow passing through said chamber thereby redirecting the supply flow into a pattern having a rotated vector, which rotated vector flow pattern upon issuing from the termination of said chamber takes the shape of a cone about said central axis exhibiting a substantially reduced pressure effect at said receiver conduit.
  • This invention relates to fiuidic elements, and more particularly to fiuidic elements having an output signal related to an input control signal thereto.
  • the prior art includes a variety of fluidic elements having an output pressure signal which is a functions of an input control pressure signal, there usually being some form of gain in the signal conversion.
  • These fiuidic devices operate on various principles.
  • a common type is the wallattachment fiuidic element in which a turbulent flow is moved between stable attached positions by the action of a control jet directed at a cross-section of the supply flow.
  • Another type is disclosed as early as Hall Patent Nos. 1,205,530 and 1,628,723, in which a laminar flow is controllably disrupted to a turbulent condition by the action of a control jet intersecting the axis of the laminar flow; the output is taken from a device sensing the distinction between the laminar and turbulent flow velocities.
  • the fluidic elements of the prior art have various limitations, the laminar-turbulence elements being susceptible to the influence of sonic noise, with a consequent unstable output signal. Additionally, the power-switching capabilities of these elements are generally restricted.
  • the wall-attachment fiuidic elements have a relatively low efliciency, and must generally operate at high pressure levels, requiring large amounts of supply air and consequently presents a high fiuidic power supply requirement in multi-element applications.
  • the present invention is directed to a fiuidic element utilizing a principle based upon redirection of a laminar flow into a pattern exhibiting a rotated vector; the receiver senses a consequent reduction in velocity from that attendant upon laminar flow in the un-redirected state.
  • This redirection is accomplished by incorporating a chamber having a fluid supply conduit thereto, with a control conduit communicating into the chamber with its axis ofl-set from the central axis of the supply tube as projected through the chamber, so that rotation may be imparted to the supply flow by the application of a control flow through the control conduit.
  • Such application of control flow operates in conjunction with the chamber configuration to redirect the supply flow through the chamber into a pattern having a substantial rotated component;
  • rotated vector applies to the entire flow, inasmuch as each particle is affected by control torquing and is rotated to some extent.
  • the velocity of the fluid taking this cone shape is most substantially reduced as compared with the velocity of laminar flow.
  • the receiver conduit senses this reduction in velocity, and provides the output for the rotated pattern fiuidic element.
  • the rotated pattern fiuidic element of the present invention provides the advantage of a relatively large powerhandling capability, the output range extending into values measured in dynamic pounds per square inch.
  • the rotated pattern fiuidic elements exhibits a relatively high pressure recovery, and is generally operable with a small power level of control flow.
  • the output of a device constructed in accordance with the invention exhibits an improved stability and insensitivity to noise sources, such as adjacent sonic sources.
  • it may be employed in many functional modes, for example, as a bistable device, an amplifier, a NOR logic element, a latching relay, or an alarm sensor.
  • the generality of application inherent in such a diversity of functions offers economies obtainable by the use of large numbers of a single standardized basic system element.
  • the novel fiuidic element of the invention utilizes a supply conduit opening into a chamber having an increased diameter as compared to the diameter of the supply conduit, the chamber having a control con duit communicating thereto with its axis displaced from the axial centerline of the flow of supply fluid passing through the chamber.
  • a receiver conduit is spaced from the flow-projecting termination of the chamber with its axis aligned with the axis of the supply conduit so that it is disposed to receive the impact of flow projection from the supply tube and the chamber combination.
  • This receiver conduit provides the output of the fiuidic element.
  • the application of a control signal to the control conduit causes a flow to be induced into the chamber superimposing a rotational component of flow pattern upon the flow issuing from the supply conduit.
  • the supply flow is redirected into a pattern exhibiting a rotated vector, which flow is projected in a cone shape having generally reduced velocities as compared with the flow velocity of the projected laminar flow in the unredirected state of operation.
  • This conical shape of the projected rotated vector flow with its generally reduced velocities transfers a low pressure to the receiver tube: this action provides for a large rangeof pressure switching between the straight laminar flow condition and the redirected condition.
  • the cooperation of the control flow off-set with the confining chamber acts upon the supply flow to produce a very low flow velocity along the central axis at a very short distance from the flow-projecting end of the chamber.
  • This location of the receiving tube in close proximity to the supply provides high impact pressure in the receiver tube when the supply flow is in the laminar mode.
  • FIGURE 1 is a three-dimensional view of an embodiment of the rotated pattern fluidic element of the invention
  • FIGURE 2 is a cross-sectional view of the embodiment along the axis thereof;
  • FIGURE 3 is a cross-section of the embodiment guiding chamber normal to the central axis thereof;
  • FIGURE 4 contains a plot of supply pressure versus output pressure for an embodiment of the invention
  • FIGURE 5 contains plots of a family of control pressure versus output pressure curves for an embodiment of the invention.
  • FIGURE 6 contains a plot of control flow versus output flow for an embodiment of the invention.
  • rotated pattern fluid element 10 is depicted in three-dimension form, consisting of supply tube 11 having its downstream end 12 connecting to chamber housing 13, and with receiver tube 14 having its sensing end 15 separated at a distance from exit orifice 16 of chamber housing 13.
  • Base member 17 has support portions 18 and 19 thereof respectively supporting tube 11 and receiver tube 14 in a manner to register the central axes thereof in alignment with central axis 20 of the rotated pattern fluidic element 10.
  • Control tubes 21 connect to and through chamber housing 13 to communicate therein with the interior recess chamber 22.
  • FIGURE 2 an illustration of an axial cross-section of the rotated pattern element 10, chamber 22 is oriented on central axis 20.
  • Supply tube 11 opens into chamber 22 at chamber supply end 23.
  • Supply tube 11 is of sufiicient length to project a laminar flow therefrom at the flow rates of interest.
  • the diameter of chamber supply end 23 is greater than the diameter of supply tube 11.
  • the transition between the diameters of supply tube 11 and chamber 22 may be a sharp one, as illustrated in FIGURE 2 at the location of supply end 23.
  • other forms of transitions may be employed, such as a conic shape of transition region instead of the right-angled transition illustrated. Indeed,
  • curvatures of any type may be employed, and the distinction between supply tube 11 and chamber 22 may not be readily apparent in some embodiments.
  • Chamber 22 is shown with an axial cross-section having a shape with opposed parallels, such as a cylinder or a box may have, but it is possible to have a wide variety of configurations, such as a bell-shape, or for that matter, shape having any convenient and desirable curvature.
  • each control tube 21 has inner termination 24 which opens into chamber 22, opening therein approximately normal to central axis 20.
  • central axis 26 of each control tube 21 is directed through chamber 22 at an offset from central axis 20, so as not to intercept central axis 20.
  • a circular cross-section is illustrated for chamber 22, but experiment shows that circularity is not essential, and chamber 22 is not necessarily limited thereto.
  • cross-sections of a wide variety of shapes may be advantageously employed, such as conveniently-fabricated square cross-sections. More generally, the cross-section of chamber 22 may include polygons of any order, with those polygons of very high orders approaching circles, ovals, and the like. It is only required that the chamber 22 shape permit the rotated vector principle to obtain.
  • FIGURES 1, 2 and 3 provides a fluidic element for redirecting a flow from supply tube 11 into a pattern having a rotated vector.
  • the configuration of flow through chamber 22 is influenced by the peripheral confining shape of chamber 22 as Well as by the rotational influence of the control flow through control tube 21.
  • the fluidic element of the invention may perform a variety of functions, according to the operating parameters selected.
  • a supply pressure is communicated to upstream end 29 of supply tube 11, and a pressure sensing device is connected to downstream end 30 of receiver tube 14, and if illustratively three of the four control tubes 21 are closed off while the remaining control tube 21 is allowed to aspirate from atmosphere through an open upstream end 27, increasing the supply pressure from zero will produce an increasing output pressure transmitted to output end 30 of receiver 14 as shown in curve 31 of FIGURE 4.
  • a suitable negative control flow pulse applied at end 27 of a control tube 21 tends to withdraw'fiow from chamber 22 and may also operate to end the latched condition of operation by restoring the laminar flow mode.
  • Increase of the supply pressure above point 32 causes the aspiration type of latching, that is, the receiver 14 output signal goes to zero when a control tube 21 is allower to aspirate. If all control tubes 21 are closed, increasing supply pressure is attended by increasing output,
  • Limiting point 34 may be utilized in some applications, such as alarm or threshold types of applications.
  • Fluidic element 10 can operate as a NOR logic element, that is, the signal at output 30 drops to 0 where ever a control input is present at any one of the control tubes 21. Absence of any control input to control tubes 21 will always result in an on or 1 logic condition if no aspiration is permitted.
  • a structure corresponding to that illustrated in FIGURES 1 through 3 has been operated having the following dimensions: supply tube 11 inside diameter, .0312 inch; free space between chamber termination 16 and receiver end 15, .25 inch; control tube 21 inside diameter, .031 inch; control tube axis 26 oft-set from central axis 20, .016 inch.
  • the control tube 21 inlet 24 into chamber 22 is located less than 10% of the chamber 22 length from end 23 thereof.
  • a structure for amplifier 10 having these dimensions may be illustratively operated with a supply pressure applied to upstream end 29 of supply tube 11 having a pressure of 20 inches of water.
  • receiver 14 may produce a signal at output end 30 thereof realizing an 85% pressure recovery, or 17.5 inches of water.
  • the application of a small control pressure, in the order of 0.20.3 inch of water to end 27 of control tube 21 typically will reduce the output signal at receiver 14 to less than 0.1 inch of water, representing a ratio of over 170 between the laminar and redirected modes of operation of amplifier 10.
  • FIGURE 5 a family of input-output curves 37, 38 and 39 is illustrated, these being respective plots for three supply pressure levels of 20 inches, inches, and 10 inches of water, with the relationship between control input pressure and receiver output pressure being illustrated for each of these supply pressures.
  • This family of curves 37, 38 and 39 applies to a fluidic element 10 structure having the dimensions given as an example above. All control tubes 21 except one are closed off.
  • Curves, 37, 38 and 39 each exhibit negative curvatures, which are the consequence of increasing aspiration as the control pressure is increased.
  • curve 37 corresponding to inches of water, shows a slowly decreasing receiver output signal starting at about 17 inches of water as the control pressure is increased from zero.
  • the receiver output pressure decreases to less than 16 inches of water as the control pressure is increased up to 0.21 inch of water.
  • reference numeral 40 This operating point is illustrated by reference numeral 40.
  • a further small increase in control pressure of 0.26 inch of water causes a sharp dro in output pressure to 10 inches of water, shown by point 41.
  • Further control pressure increases to 0.35 inch of water causes a less sharp output pressure reduction to 7 inches of water, shown by point 42.
  • control flow may be held to a substantial constant in this region, but owing to the phenomena associated with the aspiration eifects, control pressure will fluctuate over a variable range.
  • maximum oscillation occurs in the middle of point 42 and 43, when oscillation reducing to zero as points 42 or 43 are reached.
  • the operation of element 10 may include switching through a region of instability in going from a maximum receiver pressure output to a minimum.
  • Curves 38 and 39 each exhibit smaller regions of negative curvature, the aspiration effects being correspondingly less at these reduced supply pressures. Curve 39 exhibits no significant instability region, and may represent a preferable operating condition for some applications.
  • FIGURE 6 illustrates a representative plot 44 of control flow versus receiver flow.
  • an unstable output flow corresponds to the control flow region 45 associated with an oscillatory control pressure.
  • control flow held constant at point 46 for example, receiver flow will oscillate as illustrated with respect to unstable point 47 on the curve 44.
  • a lesser degree of oscillation occurs as the control flow approaches the stable regions on curve 44.
  • receiver fiow cut-01f point 48 is a stable operating point.
  • Other typical control flow versus receiver flow curve may exhibit greater or lesser regions of instability, in a manner analogous to the curves of FIGURE 2.
  • the high pressure recovery, high gain, near-zero output obtainable in the controlled state, the latching elfect in the absence of a control signal, and the good stability observed in fiuidic element 10 represent a device having marked improvements and advantages over fiuidic elements heretofore available to the art.
  • comparison with fluidic elements employing the principles illustrated in the Hall patents demonstrates a marked superiority of the present invention for a wide variety of applications.
  • Hall type fluidic elements even operating with lower supply pressures than 20 inches of water, 10 inches being a common value, cannot readily achieve a controlled output pressure reduction less than 0.5 inch of water.
  • Commercially available Hall-type elements typically exhibit on-olT pressure ratios of the order of 10 or less.
  • the pressure recovery typically available from the Hall-type elements is considerably less than obtainable from the present invention, a typical recovery for commercially available Hall-type elements being 50%.
  • the supply tube 11 and receiver tube 14 must be axially aligned; it is found convenient to make chamber 22 also axially aligned with supply tube 11 and receiver tube 14, with the diameter of chamber 22 being somewhat larger than the inside diameter of supply tube 11; control tube 21 opens into chamber 22 with its centerline 26 sufficiently off-set from axial centerline 20 of the chamber 22 to produce a rotated vector of supply flow upon application of a control flow aspiration.
  • the chamber 22 is illustratively cylindrically-shaped in the figures, but may exhibit a variety of other configurations, such as bell-shapes, cones, or configurations embodying curvatures of any description.
  • centerline 26 of control tube 21 may be tilted to project control flow partly in the direction of the supply flow, or in the alternative, tilted back toward chamber 22 end 23.
  • a fluidic element having a supply conduit and a housing defining'a chamber therein downstream from said supply conduit with the central axis of said chamber aligned with the central axis of said supply conduit and with said chamber having a diameter at its downstream termination at least as great as the general diameter of said chamber and with the inner diameter of said supply conduit as projected downstream through said chamber being spaced from the walls of said chamber so that said inner diameter of said supply conduit as projected downstream through said chamber is everywhere equidistant from said walls of said chamber throughout each plane normal to said central axis of said chamber so that in a first control condition a supply flow is projected from said supply conduit in a laminar state through said chamber and along the central axis thereof without anywhere contacting said walls of said chamber with said supply flow in said first control condition continuing in a laminar state downstream past said downstream termination of said housing, said fluidic element incorporating a control conduit opening into said chamber with the centerline of said control conduit making an angle with said central axis of said chamber and said centerline also being offset from said central axis
  • a fluidic element of claim 1 with said chamber having a volume sufliciently large to permit laminar projection of flow therethrough, but sufficiently small to cause an application of control flow to apply torque to the supply flow.

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  • Engineering & Computer Science (AREA)
  • General Engineering & Computer Science (AREA)
  • Theoretical Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Fluid Mechanics (AREA)
  • Mechanical Engineering (AREA)
  • Jet Pumps And Other Pumps (AREA)
  • Measuring Volume Flow (AREA)
  • Measuring Fluid Pressure (AREA)
US661605A 1967-08-18 1967-08-18 Rotated pattern fluidic element Expired - Lifetime US3490477A (en)

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US66160567A 1967-08-18 1967-08-18

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US (1) US3490477A (enrdf_load_stackoverflow)
DE (1) DE1774718A1 (enrdf_load_stackoverflow)
FR (1) FR1582625A (enrdf_load_stackoverflow)
GB (1) GB1230877A (enrdf_load_stackoverflow)
NL (1) NL6811494A (enrdf_load_stackoverflow)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3724476A (en) * 1971-05-10 1973-04-03 Eckardt Ag J Pneumatic amplifier

Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
NL289531A (enrdf_load_stackoverflow) * 1962-03-02
US1381096A (en) * 1921-06-07 Rotary furnace or kiln
US1628723A (en) * 1922-05-31 1927-05-17 Hall Res Corp Relay
US3182674A (en) * 1961-07-24 1965-05-11 Sperry Rand Corp System and apparatus for producing, maintaining and controlling laminar fluid streamflow
US3234955A (en) * 1962-10-01 1966-02-15 Raymond N Auger Fluid amplifiers
US3270561A (en) * 1964-04-24 1966-09-06 Gary L Smith Fluid pressure ratio sensor
US3336931A (en) * 1964-09-16 1967-08-22 Sperry Rand Corp Fluid logic vortex apparatus
US3409034A (en) * 1965-10-23 1968-11-05 Howard L. Rose Combined stream interaction and turbulent amplifiers

Patent Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1381096A (en) * 1921-06-07 Rotary furnace or kiln
US1628723A (en) * 1922-05-31 1927-05-17 Hall Res Corp Relay
US3182674A (en) * 1961-07-24 1965-05-11 Sperry Rand Corp System and apparatus for producing, maintaining and controlling laminar fluid streamflow
NL289531A (enrdf_load_stackoverflow) * 1962-03-02
US3234955A (en) * 1962-10-01 1966-02-15 Raymond N Auger Fluid amplifiers
US3270561A (en) * 1964-04-24 1966-09-06 Gary L Smith Fluid pressure ratio sensor
US3336931A (en) * 1964-09-16 1967-08-22 Sperry Rand Corp Fluid logic vortex apparatus
US3409034A (en) * 1965-10-23 1968-11-05 Howard L. Rose Combined stream interaction and turbulent amplifiers

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3724476A (en) * 1971-05-10 1973-04-03 Eckardt Ag J Pneumatic amplifier

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Publication number Publication date
DE1774718A1 (de) 1971-11-04
NL6811494A (enrdf_load_stackoverflow) 1969-02-20
GB1230877A (enrdf_load_stackoverflow) 1971-05-05
FR1582625A (enrdf_load_stackoverflow) 1969-10-03

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