US1926333A - Mechanism to control relative rotation - Google Patents
Mechanism to control relative rotation Download PDFInfo
- Publication number
- US1926333A US1926333A US479383A US47938330A US1926333A US 1926333 A US1926333 A US 1926333A US 479383 A US479383 A US 479383A US 47938330 A US47938330 A US 47938330A US 1926333 A US1926333 A US 1926333A
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- United States
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- shaft
- gear
- conduit
- rotation
- valve
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
- G05D23/00—Control of temperature
- G05D23/01—Control of temperature without auxiliary power
- G05D23/13—Control of temperature without auxiliary power by varying the mixing ratio of two fluids having different temperatures
-
- 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
- Y10T137/2496—Self-proportioning or correlating systems
- Y10T137/2514—Self-proportioning flow systems
- Y10T137/2521—Flow comparison or differential response
Definitions
- the invention is ⁇ herein illustrated as applied to meters for coordinating the relative flows of gas from two sources of supply, but the invention would be equally effective to control relative flow of liquid or electricity in any other like purposes where automatic throttling andv accelerating control is desired.
- the object of the invention is to provide a device which when once adjusted to the predetermined rotation ratio from the respective sources will automatically maintain that predetermined relationship without attention of an inspector; another object is to provide a simple and economical mechanism for the aforesaid purpose which may be constructed as a standard unit andl transported from place to place'ancl attached -to varying types of apparatus where it is desired in control relative rotary motion actuated from different sources.
- FIG. 1 is front elevation showing adaptation. of.
- Fig. 2 is enlarged detail in front elevation of the control mechanism, with top of cover partially broken away.
- Fig. 3 is vertical side view on line 3-3 of Fig. 2.
- Fig. 4 is enlarged detail front view of regulating valve mechanism with valve structure in section showing a suitable valve structure for use with the invention.
- Fig. 5 is sectional longitudinal transverse plan on line5-5 of Fig. 2.
- 6 indicates generally a mounting board which op- ⁇ tionally may have thereover a removable cover 7 46 having doors 8 therein for easy access to regulate f the valves.
- 4Mounted in any suitable manner upon the board is a pair of brackets 9 and 10 having journalled thereon as at 11 and 12a rotatable shaft 13.
- Axially mounted on shaft 13 are a collar 14, a coil spring 16, clutch plate 17, a floating driving gear 18, and a collar 19, the collars 14 and 19 being xedly keyed on the shaft 13 by means of pins 15.
- 'I'he gear 18 is freely mounted on shaft 13 and is caused normally ,to rotate in A unison therewith by means of the rotation of.
- a 'second shaft 20 in relative parallelism with shaft 13 has rotatable journalled bearings at 22 and 21 in an extension of bracket 12 and a bracket 23, respectively, and mounted collars 24 and 25 which are keyed to the shaft by pins 27 and 26.
- a spiral 28 Fixedly mounted on the shaft 20 in any suitable manner and rotatable therewith is a spiral 28 preferably having square-cut threads. Also xedly mounted on shaft 20 and rotatable therewith is a spur gear 29 in mesh with gear 18 on shaft 13 and it will be apparent that on rotation of shaft 13, the shaft 20 and the spiral 28 will normally be rotated thereby, subject, however, to
- a driving gear 39 is freely'mounted on the shaft and normally caused to rotate therewith by frictional contact with collar 35 on one side and clutch.
- plate 40 on the other side actuated in its bearing against the gear by coil spring 41 which seats o n the collar 36.
- a fourth shaft 42 is rotatably mounted and axially slldable in brackets 43 and 44.
- rack gear 46 Keyed to shaft 42 by means of collar 45 is rack gear 46 which is in mesh with gear 39 with relation to which the rack gear is adapted to oscillatory-'95 movement.
- a second spiral 48 preferably having square-cut threads. 'I'he spirals 28 and 48 are relatively meshed-and have threads of the same pitch running in opposite directions, one left hand and the other right hand.
- valves comprises a housing having an inlet 63 and outlet 64 and a bleeder 65 which latter may be regulated and adjusted in any well known manner, such as by set-screw 66.
- the valve is provided with a chamber 67 with which the inlet, outlet, and bleeder are connected.
- the chamber has mounted therein a one-way coneseated valve 68 normally maintained open by a pressure medium in the conduits 84a, the valve having a stem 70 protruding beyond the hous-
- the levers.55 and 56 have mounted ing as at 71.
- adjustable set-screws 72 and 73 respectively which, by suitable oscillation of the levers, contact with the valve stem 70 and open the valve for passage therethrough of a control medium such as air, gas, liquid, or the like.
- the one-ratio gas has a conduit 74, and the five-ratio gas has a conduit .75, each conduit having in its line a meter as indicated 76 and 77 wherein the flow therethrough causes rotary motion to be transmitted tothe respective shafts 13 4and 34 by suitable means, preferably shafts provided with universal joints 78.
- suitable means preferably shafts provided with universal joints 78.
- the conduits 74 and 75 After passing through the meters the conduits 74 and 75 have confluence into a single conduit 79 which leads to a container (not shown) for the combined mixture.
- each conduit is provided with a valve 80 and 81 operatively associated with diaphragms 83 and 82, said valves being mainf tained closed by any suitable well known means, such as a spring, and normally maintained opened by pressure on diaphragms 82 and 83 through valves 61 and 62.
- the gears 39 and 46 operated by the shaft 34 would rotate at a one-to-one speed, whereas the gear 18 on shaft 13 would rotate only once to each five rotations of the spur-gear 29, the gears being of proper relative "size to accomplish this result.
- This causes the shaft 20 and the spiral 28 thereon to rotate at the same speed as the normal speed of rotation of shaft 42 and spiral 48 thereon, when meter 77 is running with oneiifth the speed of meter 76, so that spirals 28 and 48 normally rotate in unison at the same speed.
- a constant pressure medium such as compressed air, is provided through the conduit 84 and its branches 84a to the inlet ports 63 of the valves 61, 62, and said valves are normally maintained open, thereby allowing. pressure on diaphragms which hold valves 80 and 81 open.
- the pressure on diaphragm 83 is diminished and thus permits the valve 80 to partially close, and thereby diminishing the flow of gas therethrough and,k also through meter 77, thus decreasing the speed of rotation of shaft 13 which through the gears 18 and 29 decreases the speed of rotation of spiral 28, so that it is then rotating at lesser speed than spiral 48 and causing spiral 48 to move horizontally across the threads of spiral 28 in direction of arrow A at top of Fig.
- the driving gears 18 and 39 are freely mounted on the respective shaftsl3 and 34 and are caused to rotate by clutch means 17 and 40 abutting said respective gears which construction is preferred so that if for any reason the shaft 42 should reach the limit of its hori- /tive size of gears may be altered.
- minor adjustments for sensitivity in the controller may be accom-l plished by adjusting set-screws 72 and 73 whereby said set-screws are effective to momentarily advance or delay the opening of the respective co-operating valves.
- a device to coordinate flow of fluid comprising independent fluid supply conduits, each having valve means therein to regulate iluid ow, a rotatable member connected with each supply conduit and adapted for rotation responsive to the flow of fluid through the conduit, a helically threaded spiral gear adapted for rotation by each of the said rotatable members, said spiral gears being intermeshed, and one of said gears being adapted for axial movement relative to the other gear, and means operatively responsive to the axial movement of said one gear whereby the valvesv in the fluid supply conduits may be actuated.
- a device to coordinate predetermined ratio of flow of fluid comprising independent fluid supply conduits each having a valve'meanstherenected with each supply conduit and adapted for accuses rotation responsive to the flow of fluid through a conduit, interineshing gears adapted for rotation responsive to rotation of the saidrotatable members, one of said gears V,being mounted so as to be movable longitudinally of its axis, and means operatively responsive to theaxial movement of said one gear whereby the 'valves in the fluid conduits may be actuated.
- a device to coordinate predetermined ratio of flow of iiuid comprising independent fluid movement oi said one gear whereby the valves in.
- conduits may be actuated, and clutch means interposed between the said rotatable members whereby one of said rotatable members may rotate independently wl'server the other rotatable member is at rest fi.
- device to coordinate predetermined ratio of now of iiuid comprising independent fluid supply conduits, a valve in each conduit adapted for regulating flow in a conduit, a rotatable member connected with each supply conduit and adapted for rotation responsive to flow of u'id through a conduit, interineshing oppositely threaded helicai gears adapted for rotation responsive to rotation ot said rotatable members, one of said gears being mounted so as tube movable longitudinally of its axis, means operatively responsive to the axial movement of said one gear whereby the valves in the fluid conduits may be actuated., and means associated with the last mentioned means whereby the differential in the opening and closing of the respective valves ma be adjusted.
- a device to coordinate ow of fluidsrand the like comprising a pair of independent conduits, each having therein means adapted for adjusting flow in that conduit, a rotatable member associated with each conduit and adapted for rotary determined speed of rotation of the 'respective first mentioned rotatable members ⁇ associated with the conduits.
- a device to coordinate predetermined ratio of fiows of fluids and theA like comprising a pair of conduits each having .means therein to translate a-force of flow therethrough into rotary motion, a. train of rotatable members cooperatively arranged for interrelated simultaneous rotation, said train being connected with the said respective means to translate force of flow into rotary motion, means in each conduit for adjusting the ow in that conduit, and means automatically and intermittently operative between the last mentioned adjusting means and the train of lrotatable members, two of the rotatable members in said train having differential relationship for actuating said automatically and intermittently operative means responsive to a variable inl the relative predetermined flow through the respective conduits.
- ⁇ apparatus including a rotataive member, in one conduit .adapted to give rise to a rotary motion of such member, said rotary motion being variable in accordance with rate at which duid :dows through said conduit;
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- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Engineering & Computer Science (AREA)
- Automation & Control Theory (AREA)
- Measuring Volume Flow (AREA)
Description
Sept. 12, 1933. c. N, FULCHER 1,926,333
MECHANISM T0 CONTROL RELATIV RO'IATIONl Filed sept. 2, 195o 2' sheets-sheet 1 INVENTOR. m 223ML/ BY' ATTORNEY stpt. 12, .1933. C, N FULCHER 1,926,333
inclumrsl To CONTROL RELATIVE nounou Filed Sept. 2, 1930 2 Sheets-Sheet 2 BY 6o y TMVRNEY Patented Sept. 12, 19334 v MECHANISM T CONTROL RELATIVE ROTATION charles N. mener, sin Francine, cam.
Application September 2, 1930 Serial No. 479,383
'z claims.
For purposes of exemplification the invention is` herein illustrated as applied to meters for coordinating the relative flows of gas from two sources of supply, but the invention would be equally effective to control relative flow of liquid or electricity in any other like purposes where automatic throttling andv accelerating control is desired.
The object of the invention is to provide a device which when once adjusted to the predetermined rotation ratio from the respective sources will automatically maintain that predetermined relationship without attention of an inspector; another object is to provide a simple and economical mechanism for the aforesaid purpose which may be constructed as a standard unit andl transported from place to place'ancl attached -to varying types of apparatus where it is desired in control relative rotary motion actuated from different sources.
To more fully comprehend the invention reference is directed to the accompanying drawings, wherein Fig. 1 is front elevation showing adaptation. of.,
an applied general lay-out of the invention with relation to mixture of gases from two sources.
Fig. 2 is enlarged detail in front elevation of the control mechanism, with top of cover partially broken away.
Fig. 3 is vertical side view on line 3-3 of Fig. 2. 85 Fig. 4 is enlarged detail front view of regulating valve mechanism with valve structure in section showing a suitable valve structure for use with the invention. Fig. 5 is sectional longitudinal transverse plan on line5-5 of Fig. 2.
Referring to the drawings wherein like reference characters'designate corresponding parts, 6 indicates generally a mounting board which op- \tionally may have thereover a removable cover 7 46 having doors 8 therein for easy access to regulate f the valves. 4Mounted in any suitable manner upon the board is a pair of brackets 9 and 10 having journalled thereon as at 11 and 12a rotatable shaft 13. Axially mounted on shaft 13 are a collar 14, a coil spring 16, clutch plate 17, a floating driving gear 18, and a collar 19, the collars 14 and 19 being xedly keyed on the shaft 13 by means of pins 15. 'I'he gear 18 is freely mounted on shaft 13 and is caused normally ,to rotate in A unison therewith by means of the rotation of.
A 'second shaft 20 in relative parallelism with shaft 13 has rotatable journalled bearings at 22 and 21 in an extension of bracket 12 and a bracket 23, respectively, and mounted collars 24 and 25 which are keyed to the shaft by pins 27 and 26.
Fixedly mounted on the shaft 20 in any suitable manner and rotatable therewith is a spiral 28 preferably having square-cut threads. Also xedly mounted on shaft 20 and rotatable therewith is a spur gear 29 in mesh with gear 18 on shaft 13 and it will be apparent that on rotation of shaft 13, the shaft 20 and the spiral 28 will normally be rotated thereby, subject, however, to
.ancl keyed toshaft 34 by pins 37. A driving gear 39 is freely'mounted on the shaft and normally caused to rotate therewith by frictional contact with collar 35 on one side and clutch. plate 40 on the other side actuated in its bearing against the gear by coil spring 41 which seats o n the collar 36.
In relative parallelism with the other shafts, a fourth shaft 42 is rotatably mounted and axially slldable in brackets 43 and 44. Keyed to shaft 42 by means of collar 45 is rack gear 46 which is in mesh with gear 39 with relation to which the rack gear is adapted to oscillatory-'95 movement. Also keyed to the shaft 42 as by collar 47 is a second spiral 48 preferably having square-cut threads. 'I'he spirals 28 and 48 are relatively meshed-and have threads of the same pitch running in opposite directions, one left hand and the other right hand.
It is obvious from the foregoing that upon rotation of the shaft 34, the shaft 42 and the spiral 48 will normally be rotated thereby, subject however to slippage of gear 39 hereafter explained. 105 Fixedly keyed to shaft 42 and preferably adjacent its ends are collars 49 and 50 each of which has an annular groove therein, 49a andv 50a, respectively, said grooves being adapted to receive therein a yoke, 51 and 52, respectively, which is 110 so arranged that the collar may freely rotate therein. Each yoke is provided with a tongue 53 and 54 which ride in the grooves 49a and 50a. The yokes are connected with levers 55 and 56 6 which may be oscillated on pivotal mountings 57 and 58 on brackets 59 and 60 mounted in any suitable manner on the mounting board.
While this invention is adaptable to many types of mechanisms where throttling or accelsaid valves comprises a housing having an inlet 63 and outlet 64 and a bleeder 65 which latter may be regulated and adjusted in any well known manner, such as by set-screw 66. The valve is provided with a chamber 67 with which the inlet, outlet, and bleeder are connected. The chamber has mounted therein a one-way coneseated valve 68 normally maintained open by a pressure medium in the conduits 84a, the valve having a stem 70 protruding beyond the hous- The levers.55 and 56 have mounted ing as at 71. thereon adjustable set- screws 72 and 73 respectively which, by suitable oscillation of the levers, contact with the valve stem 70 and open the valve for passage therethrough of a control medium such as air, gas, liquid, or the like.
Assume that 1t is desired to mix two gases in ratio of one-to-flve. The one-ratio gas has a conduit 74, and the five-ratio gas has a conduit .75, each conduit having in its line a meter as indicated 76 and 77 wherein the flow therethrough causes rotary motion to be transmitted tothe respective shafts 13 4and 34 by suitable means, preferably shafts provided with universal joints 78. After passing through the meters the conduits 74 and 75 have confluence into a single conduit 79 which leads to a container (not shown) for the combined mixture. Intermediate the meter and confluence each conduit is provided with a valve 80 and 81 operatively associated with diaphragms 83 and 82, said valves being mainf tained closed by any suitable well known means, such as a spring, and normally maintained opened by pressure on diaphragms 82 and 83 through valves 61 and 62. l
The gears 39 and 46 operated by the shaft 34 would rotate at a one-to-one speed, whereas the gear 18 on shaft 13 would rotate only once to each five rotations of the spur-gear 29, the gears being of proper relative "size to accomplish this result. This causes the shaft 20 and the spiral 28 thereon to rotate at the same speed as the normal speed of rotation of shaft 42 and spiral 48 thereon, when meter 77 is running with oneiifth the speed of meter 76, so that spirals 28 and 48 normally rotate in unison at the same speed. If, however, the one-ratio gas begins to pass through meter 77 at a greater ratio than oneto-iive, Athe rotation of shaft 13 increases its speed of rotation and thereby increases the speed of rotation of spiral 28 which causes the spiral 48 to move horizontally across the face of the spiral 28 in the directionof the arrowlettered B at the top of Fig. 2. Since the spiral 48 is fixedly mounted, the shaft 42 moves horizontally therewith, the rack gear 46 having sliding mesh with gear 39, and continues to rotate. 'Ihis horizontal movement of the shaft 42 in the said direction, by means of the pivoted lever 56, contacts the set-screw 73 with the protruding portion 71 of the valve stem 70 which closes the valve on its seat, thus throttling the passage through that valve. A constant pressure medium, such as compressed air, is provided through the conduit 84 and its branches 84a to the inlet ports 63 of the valves 61, 62, and said valves are normally maintained open, thereby allowing. pressure on diaphragms which hold valves 80 and 81 open. When the valve 62 is throttled or closed, the pressure on diaphragm 83 is diminished and thus permits the valve 80 to partially close, and thereby diminishing the flow of gas therethrough and,k also through meter 77, thus decreasing the speed of rotation of shaft 13 which through the gears 18 and 29 decreases the speed of rotation of spiral 28, so that it is then rotating at lesser speed than spiral 48 and causing spiral 48 to move horizontally across the threads of spiral 28 in direction of arrow A at top of Fig. 2 until spiral 48 assumes its normal position relative tospiral 28 and again rota'tes at the same speed therewith, theY shaft 42 being thereby returned to its normal position, releasing the contact between set-screw 73 and the valve stem 71, and opening the valve 62 which in turn opens valve 80. A like action as applied to valve 61 through lever 55 would occur if shaft 34 were caused to increase speed of rotation by the gas ow through meter 76 increasing above the predetermined ratio which in the example is one-to-ve. Like- Wse, if the ow from either source is decreased below the one-to-iive ratio a relatively similar, movement of shaft`42 would take place and thus 110 coordinate the flow.
As above stated, the driving gears 18 and 39 are freely mounted on the respective shaftsl3 and 34 and are caused to rotate by clutch means 17 and 40 abutting said respective gears which construction is preferred so that if for any reason the shaft 42 should reach the limit of its hori- /tive size of gears may be altered. In the exemplication herein described minor adjustments for sensitivity in the controller may be accom-l plished by adjusting set- screws 72 and 73 whereby said set-screws are effective to momentarily advance or delay the opening of the respective co-operating valves. r
Having thus described my invention, what I. claim and desire to secure through Letters Pat-l` ent is:
i. A device to coordinate flow of fluid, comprising independent fluid supply conduits, each having valve means therein to regulate iluid ow, a rotatable member connected with each supply conduit and adapted for rotation responsive to the flow of fluid through the conduit, a helically threaded spiral gear adapted for rotation by each of the said rotatable members, said spiral gears being intermeshed, and one of said gears being adapted for axial movement relative to the other gear, and means operatively responsive to the axial movement of said one gear whereby the valvesv in the fluid supply conduits may be actuated.
2. A device to coordinate predetermined ratio of flow of fluid, comprising independent fluid supply conduits each having a valve'meanstherenected with each supply conduit and adapted for accuses rotation responsive to the flow of fluid through a conduit, interineshing gears adapted for rotation responsive to rotation of the saidrotatable members, one of said gears V,being mounted so as to be movable longitudinally of its axis, and means operatively responsive to theaxial movement of said one gear whereby the 'valves in the fluid conduits may be actuated.
3. A device to coordinate predetermined ratio of flow of iiuid, comprising independent fluid movement oi said one gear whereby the valves in.
the fluid. conduits may be actuated, and clutch means interposed between the said rotatable members whereby one of said rotatable members may rotate independently wl'iile the other rotatable member is at rest fi. e. device to coordinate predetermined ratio of now of iiuid, comprising independent fluid supply conduits, a valve in each conduit adapted for regulating flow in a conduit, a rotatable member connected with each supply conduit and adapted for rotation responsive to flow of u'id through a conduit, interineshing oppositely threaded helicai gears adapted for rotation responsive to rotation ot said rotatable members, one of said gears being mounted so as tube movable longitudinally of its axis, means operatively responsive to the axial movement of said one gear whereby the valves in the fluid conduits may be actuated., and means associated with the last mentioned means whereby the differential in the opening and closing of the respective valves ma be adjusted.
5. A device to coordinate ow of fluidsrand the like, comprising a pair of independent conduits, each having therein means adapted for adjusting flow in that conduit, a rotatable member associated with each conduit and adapted for rotary determined speed of rotation of the 'respective first mentioned rotatable members` associated with the conduits. v
6. A device to coordinate predetermined ratio of fiows of fluids and theA like, .comprising a pair of conduits each having .means therein to translate a-force of flow therethrough into rotary motion, a. train of rotatable members cooperatively arranged for interrelated simultaneous rotation, said train being connected with the said respective means to translate force of flow into rotary motion, means in each conduit for adjusting the ow in that conduit, and means automatically and intermittently operative between the last mentioned adjusting means and the train of lrotatable members, two of the rotatable members in said train having differential relationship for actuating said automatically and intermittently operative means responsive to a variable inl the relative predetermined flow through the respective conduits.
i. .a device adapted to maintain a desired ratio of 'flow in two separate fluid conduits, comprising two separate duid conduits;` apparatus, including a rotataive member, in one conduit .adapted to give rise to a rotary motion of such member, said rotary motion being variable in accordance with rate at which duid :dows through said conduit; a
separate apparatus in the other conduit and including a rotatave member, adapted to give rise to a rotary motion. of such member, said rotary motion being variable in accordance with the rate at which :duid flows through said conduit;
a longitudinally dried spiral gear driven by one 1
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US479383A US1926333A (en) | 1930-09-02 | 1930-09-02 | Mechanism to control relative rotation |
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US479383A US1926333A (en) | 1930-09-02 | 1930-09-02 | Mechanism to control relative rotation |
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US1926333A true US1926333A (en) | 1933-09-12 |
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Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2522411A (en) * | 1943-09-24 | 1950-09-12 | Honeywell Regulator Co | Control device |
US2626787A (en) * | 1947-02-21 | 1953-01-27 | Omega Machine Company | Proportioning device |
US2795235A (en) * | 1955-07-13 | 1957-06-11 | Great Lakes Pipe Line Company | Apparatus for automatic flow control in conduits |
US2865345A (en) * | 1955-11-02 | 1958-12-23 | California Research Corp | Fluid flow proportioning |
US2870776A (en) * | 1954-06-21 | 1959-01-27 | Sun Oil Co | Liquid proportioning system |
US2977970A (en) * | 1955-11-25 | 1961-04-04 | Sun Oil Co | Metering means |
US3092129A (en) * | 1960-04-08 | 1963-06-04 | Smith Corp A O | Liquid blending control |
US3408800A (en) * | 1965-04-26 | 1968-11-05 | Louis F. Jezek Jr. | Cotton stripping fingers |
-
1930
- 1930-09-02 US US479383A patent/US1926333A/en not_active Expired - Lifetime
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2522411A (en) * | 1943-09-24 | 1950-09-12 | Honeywell Regulator Co | Control device |
US2626787A (en) * | 1947-02-21 | 1953-01-27 | Omega Machine Company | Proportioning device |
US2870776A (en) * | 1954-06-21 | 1959-01-27 | Sun Oil Co | Liquid proportioning system |
US2795235A (en) * | 1955-07-13 | 1957-06-11 | Great Lakes Pipe Line Company | Apparatus for automatic flow control in conduits |
US2865345A (en) * | 1955-11-02 | 1958-12-23 | California Research Corp | Fluid flow proportioning |
US2977970A (en) * | 1955-11-25 | 1961-04-04 | Sun Oil Co | Metering means |
US3092129A (en) * | 1960-04-08 | 1963-06-04 | Smith Corp A O | Liquid blending control |
US3408800A (en) * | 1965-04-26 | 1968-11-05 | Louis F. Jezek Jr. | Cotton stripping fingers |
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