US3282282A - Fluid power output device - Google Patents
Fluid power output device Download PDFInfo
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- US3282282A US3282282A US34577964A US3282282A US 3282282 A US3282282 A US 3282282A US 34577964 A US34577964 A US 34577964A US 3282282 A US3282282 A US 3282282A
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- Prior art keywords
- fluid
- channel
- stream
- power
- output
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15C—FLUID-CIRCUIT ELEMENTS PREDOMINANTLY USED FOR COMPUTING OR CONTROL PURPOSES
- F15C1/00—Circuit elements having no moving parts
- F15C1/08—Boundary-layer devices, e.g. wall-attachment amplifiers coanda effect
-
- Y—GENERAL 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
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T137/00—Fluid handling
- Y10T137/206—Flow affected by fluid contact, energy field or coanda effect [e.g., pure fluid device or system]
- Y10T137/2229—Device including passages having V over T configuration
- Y10T137/2256—And enlarged interaction chamber
Definitions
- the present invention relates to the field of fluidamplifiers, and particularly, to a fluid power output device which minimizes the power consumption of a fluid system.
- Fluid amplifiers operate upon the principle that a fluid power jet stream of relatively high energy may be deflected without losing its integrity generally and preferably by means of a fluid control stream of lesser energy.
- a typical pure fluid amplifier includes a fluid interaction chamber wherein an entering power stream is deflected into either one of two output channels by means of a control stream impinging thereon at substantially a right angle.
- Certain types of fluid amplifiers exhibit bistable flip-flop characteristics in that power stream flow remains entirely in a selected output channel even after termination of the control input.
- Other types of fluid amplifiers such as logical OR and NOR gates, can also exhibit a digital types of response without being bistable in nature.
- the power stream output obtained from a pure fluid logic system must have suflicient energy to operate mechanical mechanism such as an output printer or the like.
- mechanical mechanism such as an output printer or the like.
- the power stream flow is continuous no matter through which amplifier output channel it is directed, i.e., the power stream remains on even during the time that the mechanical mechanism is inoperative.
- the efliciency of the unit is considerably decreased since the power stream source performs work upon the fluid being exhausted. Consequently, if the energy in the power stream is required to be large because of the need for actuating a mechanical device, a considerable amount of power is wasted at various times in the system operation.
- the present invention discloses means for producing large output fluid power from a fluid amplifier digital system only when it is actually required to perform some significant function. Instead of utilizing the power stream of a fluid amplifier to directly actuate mechanical elements of a large mass, a digital type fluid amplifier power stream of relatively low energy is used to move a mechanical valve element of relatively low mass to a position which either blocks or permits flow of a fluid stream of relatively large energy through a separate independent channel. This relatively high energy stream in 'turn provides the output fluid power necessary. Consequently, although the fluid amplifier power stream is continuously generated as usual, the power loss resulting from its constant operation is negligible compared to the power saved by blocking the flow of the high energy stream in the separate channel during those times when no significant output function need be performed.
- Another object of the present invention is to provide means of producing relatively high fluid output power only when required.
- a further object of the present invention is to provide a unique combination including a digital type of fluid amplifier whose output power stream controls the positioning of a spool valve element which in turn blocks 3,282,282 Patented Nov. 1, 1966 or permits flow of relatively high energy fluid in a separate channel.
- FIGURES 1 and 2 are the plan and side elevation views, respectively, of one embodiment of the present invention.
- FIGURE 3 is a plan View showing a modification of the embodiment in FIGURES 1 and 2.
- the pure fluid amplifier channels, the valve seat, and the utilization fluid channel may be formed or molded in a, body 10 of transparent plastic material or the like, with said channels having side walls extending entirely therethrough.
- the top and bottom walls of the channels are formed by plastic covers 12 and 14, respectively, which are attached to body 10 by means of threaded fastening screws 16.
- a fluid utilization channel 18 is provided having input and output ports 20 and 22, respectively, which are drilled into cover 14 at right angles.
- High energy fluid under pressure is constantly supplied to port 20 via an external conduit 24 from a fluid pressure source 26.
- the fluid flow in chan nel 18 exits from body 10 by means of port 22, and from thence through external conduit 28 to a utilization device 30 which in turn may be comprised of mechanism actuated by the energy of the. fluid stream.
- Fluid flow in channel 18 is governed by the position of a spool valve 32 which is slidably located in a valve seat channel 34 intersecting fluid channel 18.
- the spoolvalve 32 is comprised of two end lands 36 and 38 which are connected by a center portion 40 of considerably reduced cross-sectional area.
- valve 32 When valve 32 is in its leftmost position as shown in FIGURE 1, center portion 40 lies athwart fluid channel 18 and thereby permits substantial fluid flow in said channel from source 26 to utilization device 30. On the other hand, if valve 32 is positioned in its rightmost position so that it abuts against the right end of channel 34, then land 36 lies athwart channel 18 and completely blocks the flow of fluid therein. Therefore, energy may be selectively applied to utilization device 30 depending upon the position of valve 32, there being no energy wasted from source 26 with said valve in its right hand position.
- spool valve 32 The positioning of spool valve 32 in turn is governed by the output from a digital type pure fluid amplifier generally indicated by 42.
- This pure fluid amplifier is comprised of a power stream input channel 44 and two power stream output channels 46 and 48.
- Power stream input channel 44 emerges into a fluid interaction chamber 50 via a nozzle 52, so that a power jet stream is formed in the manner well known in the art.
- Power input channel 44 is supplied fluid under pressure from an external source 54 via conduit 56 and port 58 drilled at right angles to body 10.
- the inner walls 60 and 62 of output channels 46 and 48 come together to form a divider knife edge 64 which is located on the axis of orifice 52.
- 'Output channels 46 and 48 in turn respectively communicate with the left and right, ends of valve seat channel 34 by means of fluid ports 64 and 66.
- a fluid power jet stream entering the interaction chamber of a digital type pure fluid amplifier can be deflected, without losing its integrity, so as to enter only one of its two output channels. That is to say, the absence or presence of power streams fluid in a particular power stream output channel can be representative of a discrete control function or of a digital value in a number system. This deflection in turn is accomplished by an even lower energy control jet stream impinging upon the power stream at right angles thereto in the vicinity of the interaction chamber.
- two control stream input channels 68 and 70 are provided each having an inlet '72 and 74, respectively, from some external fluid source.
- control stream channel 70 one such source 80 is shown for the control stream channel 70, said source 80 possibly being another fluid amplifier whose power output stream is used as the control stream for amplifier 42.
- Control channels 68 and 70 open into interaction chamber 50 via nozzles 82 and 84. If a power jet stream issues from nozzle 52 into interaction chamber 50, then a control stream issuing from channel 68 will deflect the power stream in the direction of the solid arrow so that said power stream flows into output channel 48. On the other hand, if a control stream from channel 70 instead issues into interaction chamber 50, it deflects the power stream from channel 44 into output channel 46 as indicated by the dotted arrow.
- the digital type pure fluid amplifier 42 also has a bistable characteristic such that power stream flow in either output channel 46 or 48 is maintained even after termination of the initiating control stream.
- This bistable characteristic may be conveniently provided by the so-called boundary layer phenomenon, well known to the prior art, which causes the power stream to automatically lock on to the outer side wall of a channel to which it is deflected.
- boundary layer phenomenon well known to the prior art, which causes the power stream to automatically lock on to the outer side wall of a channel to which it is deflected.
- the temporary emission of control stream fluid from channel 70 pushes the power stream over to output wall 86 so that said power stream commences to flow in output channel 46.
- the entrainment of fluid from the region between wall 86 and the power stream causes a reduction of pressure here which acts by itself to keep the power stream flowing in this path.
- the control stream from channel 70 may now be terminated without the power stream leaving output channel 46. Consequently, the amplifier is stable for this output since no control stream need be continuously applied thereafter.
- a control stream is caused to flow temporarily from channel 68 which provides fluid to this region, increases the pressure therein, and thereby pushes the power stream into channel 48 where it locks on to outer wall 88.
- the control stream in channel 68 may now be discontinued, but the power stream remains flowing in channel 48.
- the formation of this boundary layer may be enhanced by slightly olfsetting side walls 86 and 88 with respect to nozzle 52 in the manner shown in FIGURE 1.
- Exhaust channels 90 and 92 are further provided for respective channels 46 and 48 in order to permit the escape of power stream mass flow in order to avoid a reversal of same within an output channel which in turn would result in fluid pressure appearing in both channels 46 and 48 at the same time.
- These exhaust channels are preferably constricted and/or oriented at an acute angle with the upstream power fluid so as to permit suflicient pressure to be built up for operating and moving the spool valve, and they exit from body via ports 94 and 96. Also, each exhaust channel prevents the back pressure from building up in the output channel wherein power stream flow occurs.
- this back pressure relief is necessary to avoid undesirable switching of the power stream between output channels in the absence of control stream flow, since very often the boundary layer lock on effect, which provides power stream stability in an output channel, can be destroyed if said back pressure is above a certain threshold value.
- Fluid flow in output channel 48 causes an unbalanced force to be applied to spool valve 32 such that it is moved to its leftmost position which thereby prevents fluid flow in channel 18.
- power stream flow in channel 46 applies an unbalanced force on spool valve 32 in order to move it to its rightmost position so that land 36 completely blocks channel 18. Since the spool valve body moves transverse to the high energy stream only a small pressure against its end is required to actuate it because there is no work done against the force of the high energy stream. This means that the relatively low energy of a typical fluid amplifier power stream is quite capable and admirably suited for operating this type of mechanical valve element.
- a relatively low energy power stream flow in either channel 46 or channel 48 causes the positioning of a valve 32 which in turn controls a relatively higher energy fluid stream in channel 18.
- power stream flow in the fluid amplifier 42 usually is continuous no matter to which channel it is deflected. However, the loss of energy occasioned by this flow, when there is no need to energize the mechanism 30, is relatively small compared to the energy supplied by source 26 which is itself not wasted when valve 32 is in its blocking position.
- FIGURE 3 shows a slightly modified arrangement of the basic embodiment in which the exhaust channels and 102 actually communicate with valve seat channel 34.
- an exhaust channel is not open to a power stream output channel 46 or 48 until spool valve 32 is correctly positioned.
- Such a configuration may be advantageous where the exhaust pressure exsting at a port 94 or 96 in FIGURE 1 might be of such low value that the stability of power stream flow in amplifier 42 of the boundary layer type would be affected because of unwanted low pressure feedback via the non-selected channel 46 or 48 to the chamber 50.
- a more important rea son, however, is that the FIGURE 3 arrangement prevents escape of the power stream mass flow until the spool valve is at least partially repositioned which thus permits the application of a higher initial actuating force to the valve.
- a fluid device which comprises:
- a utilization channel having an inlet connected to said first source and an outlet which in turn is adapted for connection with utilization means
- valve seat channel intersecting said utilization channel, said valve seat channel having first and second fluid ports at first and second ends thereof, respectively;
- a spool valve member having first and second end surfaces which is slideably mounted in said valve seat channel With its first and second end surfaces exposed to said first and second fiuid ports, respectively, and movable by fluid pressure selectively applied to its first and second end surfaces to a first position at one end of said valve seat channel wherein said spool valve member blocks flow through said utilization channel of said utilization fluid stream and movable to a sec-0nd position at the other end of said valve seat channel wherein said spool valve member permits flow through said utilization channel of said utilization fluid stream;
- a digital type fluid amplifier including a power stream input channel connected to said second source, and at least first and second power stream output channels respectively connected with said first and second fluid ports;
- control means connected with said fluid amplifier for selectively directly its said power fluid stream into either of said first or second power stream output 5 channels;
- first and second exhaust channels coaxial with the valve seat channel and respectively communicating with said first and second power stream output channels at locations immediately exterior to the respective 10 end of said valve seat channel so that said exhaust channels are continuously operable to exhaust fluid from said valve seat channel and said power stream output channels at all times irrespective of the position of said spool valve member in said valve seat 15 channel.
- control means comprises selectively operable nozzle means.
Description
Nov. 1, 1966 E. u. SOWERS 111 3,282,232
. FLUID POWER OUTPUT DEVICE Filed Feb. 18, 1964 2 Sheets-Sheet 1 FIG. 1 22 EXHAUST w /EXHAUST as as I," 68 70 J/ 52 1 44 1s 16 1 10o A Q FIG 3 INVENTOR EDWIN u. sowERsnl A TTORNE Y5 Nov. 1, 1966 E. u. SOWERS 111 3,282,282
FLUID PQWER OUTPUT DEVICE Filed Feb. 18, 1964 2 Sheets-Sheet 2 United States Patent 3,282,282 FLUID POWER OUTPUT DEVICE Edwin U. Sewers III, Silver Spring, Md., assignor to Sperry Rand Corporation, New York, N.Y., a corporation of Delaware Filed Feb. 18, 1964, Ser. No. 345,779 3 Claims. (Cl. 137-815) The present invention relates to the field of fluidamplifiers, and particularly, to a fluid power output device which minimizes the power consumption of a fluid system.
Fluid amplifiers, as the term is now employed, operate upon the principle that a fluid power jet stream of relatively high energy may be deflected without losing its integrity generally and preferably by means of a fluid control stream of lesser energy. In general, a typical pure fluid amplifier includes a fluid interaction chamber wherein an entering power stream is deflected into either one of two output channels by means of a control stream impinging thereon at substantially a right angle. Certain types of fluid amplifiers exhibit bistable flip-flop characteristics in that power stream flow remains entirely in a selected output channel even after termination of the control input. Other types of fluid amplifiers, such as logical OR and NOR gates, can also exhibit a digital types of response without being bistable in nature. In some instances, the power stream output obtained from a pure fluid logic system must have suflicient energy to operate mechanical mechanism such as an output printer or the like. In the prior art it is customary to directly connect one output channel of the amplifier to the mechanical device while the other output channel is connected to exhaust the power stream back to the source of fluid pressure. The power stream flow is continuous no matter through which amplifier output channel it is directed, i.e., the power stream remains on even during the time that the mechanical mechanism is inoperative. In such a situation, the efliciency of the unit is considerably decreased since the power stream source performs work upon the fluid being exhausted. Consequently, if the energy in the power stream is required to be large because of the need for actuating a mechanical device, a considerable amount of power is wasted at various times in the system operation.
The present invention discloses means for producing large output fluid power from a fluid amplifier digital system only when it is actually required to perform some significant function. Instead of utilizing the power stream of a fluid amplifier to directly actuate mechanical elements of a large mass, a digital type fluid amplifier power stream of relatively low energy is used to move a mechanical valve element of relatively low mass to a position which either blocks or permits flow of a fluid stream of relatively large energy through a separate independent channel. This relatively high energy stream in 'turn provides the output fluid power necessary. Consequently, although the fluid amplifier power stream is continuously generated as usual, the power loss resulting from its constant operation is negligible compared to the power saved by blocking the flow of the high energy stream in the separate channel during those times when no significant output function need be performed.
It is therefore one object of the present invention to provide -a fluid power output device which minimizes the power consumption of a fluid system.
Another object of the present invention is to provide means of producing relatively high fluid output power only when required.
A further object of the present invention is to provide a unique combination including a digital type of fluid amplifier whose output power stream controls the positioning of a spool valve element which in turn blocks 3,282,282 Patented Nov. 1, 1966 or permits flow of relatively high energy fluid in a separate channel.
These and other objects of the present invention will become apparent during the course of the following description to be read in view of the drawings, in which:
FIGURES 1 and 2 are the plan and side elevation views, respectively, of one embodiment of the present invention; and
FIGURE 3 is a plan View showing a modification of the embodiment in FIGURES 1 and 2.
Referring now to FIGURES 1 and 2, a preferred embodiment of the present invention will be described in which the output from a pure fluid digital type amplifier controls the position of a spool valve, which in turn blocks or permits flow of fluid in a channel leading to some utilization device such as a printer. The pure fluid amplifier channels, the valve seat, and the utilization fluid channel may be formed or molded in a, body 10 of transparent plastic material or the like, with said channels having side walls extending entirely therethrough. The top and bottom walls of the channels are formed by plastic covers 12 and 14, respectively, which are attached to body 10 by means of threaded fastening screws 16. A fluid utilization channel 18 is provided having input and output ports 20 and 22, respectively, which are drilled into cover 14 at right angles. High energy fluid under pressure is constantly supplied to port 20 via an external conduit 24 from a fluid pressure source 26. The fluid flow in chan nel 18 exits from body 10 by means of port 22, and from thence through external conduit 28 to a utilization device 30 which in turn may be comprised of mechanism actuated by the energy of the. fluid stream. Fluid flow in channel 18 is governed by the position of a spool valve 32 which is slidably located in a valve seat channel 34 intersecting fluid channel 18. As best shown in FIGURE 1, the spoolvalve 32 is comprised of two end lands 36 and 38 which are connected by a center portion 40 of considerably reduced cross-sectional area. When valve 32 is in its leftmost position as shown in FIGURE 1, center portion 40 lies athwart fluid channel 18 and thereby permits substantial fluid flow in said channel from source 26 to utilization device 30. On the other hand, if valve 32 is positioned in its rightmost position so that it abuts against the right end of channel 34, then land 36 lies athwart channel 18 and completely blocks the flow of fluid therein. Therefore, energy may be selectively applied to utilization device 30 depending upon the position of valve 32, there being no energy wasted from source 26 with said valve in its right hand position.
The positioning of spool valve 32 in turn is governed by the output from a digital type pure fluid amplifier generally indicated by 42. This pure fluid amplifier is comprised of a power stream input channel 44 and two power stream output channels 46 and 48. Power stream input channel 44 emerges into a fluid interaction chamber 50 via a nozzle 52, so that a power jet stream is formed in the manner well known in the art. Power input channel 44 is supplied fluid under pressure from an external source 54 via conduit 56 and port 58 drilled at right angles to body 10. The inner walls 60 and 62 of output channels 46 and 48 come together to form a divider knife edge 64 which is located on the axis of orifice 52. ' Output channels 46 and 48 in turn respectively communicate with the left and right, ends of valve seat channel 34 by means of fluid ports 64 and 66.
As is well known by those skilled in pure fluid technology, a fluid power jet stream entering the interaction chamber of a digital type pure fluid amplifier can be deflected, without losing its integrity, so as to enter only one of its two output channels. That is to say, the absence or presence of power streams fluid in a particular power stream output channel can be representative of a discrete control function or of a digital value in a number system. This deflection in turn is accomplished by an even lower energy control jet stream impinging upon the power stream at right angles thereto in the vicinity of the interaction chamber. In FIGURE 1, two control stream input channels 68 and 70 are provided each having an inlet '72 and 74, respectively, from some external fluid source. In FIGURE 2, one such source 80 is shown for the control stream channel 70, said source 80 possibly being another fluid amplifier whose power output stream is used as the control stream for amplifier 42. Control channels 68 and 70 open into interaction chamber 50 via nozzles 82 and 84. If a power jet stream issues from nozzle 52 into interaction chamber 50, then a control stream issuing from channel 68 will deflect the power stream in the direction of the solid arrow so that said power stream flows into output channel 48. On the other hand, if a control stream from channel 70 instead issues into interaction chamber 50, it deflects the power stream from channel 44 into output channel 46 as indicated by the dotted arrow.
The digital type pure fluid amplifier 42 also has a bistable characteristic such that power stream flow in either output channel 46 or 48 is maintained even after termination of the initiating control stream. In other words, it is a fluid flip-flop device. This bistable characteristic may be conveniently provided by the so-called boundary layer phenomenon, well known to the prior art, which causes the power stream to automatically lock on to the outer side wall of a channel to which it is deflected. As an example, the temporary emission of control stream fluid from channel 70 pushes the power stream over to output wall 86 so that said power stream commences to flow in output channel 46. The entrainment of fluid from the region between wall 86 and the power stream causes a reduction of pressure here which acts by itself to keep the power stream flowing in this path. The control stream from channel 70 may now be terminated without the power stream leaving output channel 46. Consequently, the amplifier is stable for this output since no control stream need be continuously applied thereafter. When it is desired to divert the power stream into output channel 48, a control stream is caused to flow temporarily from channel 68 which provides fluid to this region, increases the pressure therein, and thereby pushes the power stream into channel 48 where it locks on to outer wall 88. The control stream in channel 68 may now be discontinued, but the power stream remains flowing in channel 48. The formation of this boundary layer may be enhanced by slightly olfsetting side walls 86 and 88 with respect to nozzle 52 in the manner shown in FIGURE 1.
Fluid flow in output channel 48 causes an unbalanced force to be applied to spool valve 32 such that it is moved to its leftmost position which thereby prevents fluid flow in channel 18. On the other hand, power stream flow in channel 46 applies an unbalanced force on spool valve 32 in order to move it to its rightmost position so that land 36 completely blocks channel 18. Since the spool valve body moves transverse to the high energy stream only a small pressure against its end is required to actuate it because there is no work done against the force of the high energy stream. This means that the relatively low energy of a typical fluid amplifier power stream is quite capable and admirably suited for operating this type of mechanical valve element. Thus, a relatively low energy power stream flow in either channel 46 or channel 48 causes the positioning of a valve 32 which in turn controls a relatively higher energy fluid stream in channel 18. No additional valve biasing means need be provided here to maintain said valve in one position or the other. It will be' noted that power stream flow in the fluid amplifier 42 usually is continuous no matter to which channel it is deflected. However, the loss of energy occasioned by this flow, when there is no need to energize the mechanism 30, is relatively small compared to the energy supplied by source 26 which is itself not wasted when valve 32 is in its blocking position.
FIGURE 3 shows a slightly modified arrangement of the basic embodiment in which the exhaust channels and 102 actually communicate with valve seat channel 34. In this figure, an exhaust channel is not open to a power stream output channel 46 or 48 until spool valve 32 is correctly positioned. Such a configuration may be advantageous where the exhaust pressure exsting at a port 94 or 96 in FIGURE 1 might be of such low value that the stability of power stream flow in amplifier 42 of the boundary layer type would be affected because of unwanted low pressure feedback via the non-selected channel 46 or 48 to the chamber 50. A more important rea son, however, is that the FIGURE 3 arrangement prevents escape of the power stream mass flow until the spool valve is at least partially repositioned which thus permits the application of a higher initial actuating force to the valve.
Although preferred embodiments of the present invention have been shown and described, it is apparent that may modifications will occur to those skilled in the art without departing from the spirit of the invention as defined in the appended claims.
The embodiments of the invention in which an exclu sive property or privilege is claimed are defined as follows:
1. A fluid device which comprises:
a first source of relatively high energy utilization fluid stream;
a utilization channel having an inlet connected to said first source and an outlet which in turn is adapted for connection with utilization means;
an elongated valve seat channel intersecting said utilization channel, said valve seat channel having first and second fluid ports at first and second ends thereof, respectively;
a spool valve member having first and second end surfaces which is slideably mounted in said valve seat channel With its first and second end surfaces exposed to said first and second fiuid ports, respectively, and movable by fluid pressure selectively applied to its first and second end surfaces to a first position at one end of said valve seat channel wherein said spool valve member blocks flow through said utilization channel of said utilization fluid stream and movable to a sec-0nd position at the other end of said valve seat channel wherein said spool valve member permits flow through said utilization channel of said utilization fluid stream;
a second source of relatively low energy power fluid stream;
a digital type fluid amplifier including a power stream input channel connected to said second source, and at least first and second power stream output channels respectively connected with said first and second fluid ports;
control means connected with said fluid amplifier for selectively directly its said power fluid stream into either of said first or second power stream output 5 channels; and
first and second exhaust channels coaxial with the valve seat channel and respectively communicating with said first and second power stream output channels at locations immediately exterior to the respective 10 end of said valve seat channel so that said exhaust channels are continuously operable to exhaust fluid from said valve seat channel and said power stream output channels at all times irrespective of the position of said spool valve member in said valve seat 15 channel.
6 2. A fluid device of the type according to claim 1 wherein said fluid amplifier is of the boundary layer bistable type.
3. A fluid device according to claim 2 wherein said control means comprises selectively operable nozzle means.
References Cited by the Examiner UNITED STATES PATENTS 3,124,999 3/1964 Woodward 137-815 3,181,546 5/1965 Boothe 13781.5 3,187,762 6/1965 Norwood 1378l.5 3,208,448 9/1965 Woodward 1378l.5
M. CARY NELSON, Primary Examiner.
W. CLINE, Assistant Examiner.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US34577964 US3282282A (en) | 1964-02-18 | 1964-02-18 | Fluid power output device |
Applications Claiming Priority (1)
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US34577964 US3282282A (en) | 1964-02-18 | 1964-02-18 | Fluid power output device |
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US3282282A true US3282282A (en) | 1966-11-01 |
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US34577964 Expired - Lifetime US3282282A (en) | 1964-02-18 | 1964-02-18 | Fluid power output device |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3439695A (en) * | 1965-09-29 | 1969-04-22 | Bowles Eng Corp | Fluid-driven timing mechanism |
US3521653A (en) * | 1967-12-13 | 1970-07-28 | Sperry Rand Corp | Power transmission |
US3722364A (en) * | 1970-04-15 | 1973-03-27 | Dba Sa | Reciprocating fluid motor |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3124999A (en) * | 1964-03-17 | Fluid oscillator | ||
US3181546A (en) * | 1962-11-08 | 1965-05-04 | Gen Electric | Fluid control devices |
US3187762A (en) * | 1962-12-10 | 1965-06-08 | Ibm | Electro-fluid apparatus |
US3208448A (en) * | 1962-02-02 | 1965-09-28 | Kenneth E Woodward | Artificial heart pump circulation system |
-
1964
- 1964-02-18 US US34577964 patent/US3282282A/en not_active Expired - Lifetime
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3124999A (en) * | 1964-03-17 | Fluid oscillator | ||
US3208448A (en) * | 1962-02-02 | 1965-09-28 | Kenneth E Woodward | Artificial heart pump circulation system |
US3181546A (en) * | 1962-11-08 | 1965-05-04 | Gen Electric | Fluid control devices |
US3187762A (en) * | 1962-12-10 | 1965-06-08 | Ibm | Electro-fluid apparatus |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3439695A (en) * | 1965-09-29 | 1969-04-22 | Bowles Eng Corp | Fluid-driven timing mechanism |
US3521653A (en) * | 1967-12-13 | 1970-07-28 | Sperry Rand Corp | Power transmission |
US3722364A (en) * | 1970-04-15 | 1973-03-27 | Dba Sa | Reciprocating fluid motor |
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