Fluid inductor system and apparatus having deformable member for controlling fluid flow

Abstract
An apparatus for mixing fluids includes a housing which is mounted in line with a conduit carrying a primary fluid. A deformable member is mounted in the housing and an inlet conduit carrying a secondary fluid communicates with the deformable member. An adjustment knob adjusts the width of the deformable member, thereby adjusting the venturi effect created by the deformable member in the flow of primary fluid and adjusting the flow of secondary fluid which flows into the deformable member and is induced out of the deformable member through a plurality of holes to mix with the primary fluid. A system is provided with the fluid inductor apparatus and includes a sensor at the fluid outlet to generate a signal to control the geometric profile of the deformable member to adjust mixing of the fluids.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates generally to fluid flow control apparatus and systems and more particularly, to apparatus for introducing a secondary fluid into a primary fluid system and controlling mixing of the primary and secondary fluids.




2. Description of the Related Art




The prior art includes various examples of apparatus for the mixing of the fluid streams, included among which are the following U.S. Patents.




U.S. Pat. No. 907,851 to Munson discloses a flume gate in which a movable gate is mounted in a gate holder which includes cylindrical springs. The flume gate can be moved to adjust the flow through the flume.




U.S. Pat. No. 2,968,919 to Hughes et al discloses a variable area nozzle in which circumferentially spaced vanes are provided in a nozzle throat. The position of the vanes can be adjusted to restrict the flow of fluid through the nozzle in response to changes in pressure upstream from the throat.




U.S. Pat. No. 4,087,862 to Tsein discloses a bladeless mixing device in which streams are tangentially directed into an inlet mixing chamber in which a converging vortex is created which passes through an orifice into an outlet mixing chamber in which a diverging vortex is created. The stream leaves the outlet mixing chamber in a tangential direction for subsequent passage through further stages of the mixing device which include additional inlet and outlet mixing chambers.




U.S. Pat. No. 4,103,351 to Mamyriisky discloses an apparatus for controlling the density of a plugging fluid for oil and gas wells which includes an orifice which is rotatable about its longitudinal axis in the area of mixing a dry cementation material. The orifice produces a flat jet stream which rotates and mixes the dry cementation material.




U.S. Pat. No. 4,123,800 to Mazzei discloses a mixer-injector apparatus in which a throat portion having a portion of decreasing and increasing diameter is disposed between a carrier stream inlet and outlet. A port discharges additive fluid into the throat portion.




U.S. Pat. No. 4,415,275 to Dietrich discloses a swirl mixing device in which a first injector injects a first fluid into a first injection chamber and a second injector injects a second fluid into a second injector chamber. The two fluids have opposite angular momentum and meet near an opening in a collar separating the two chambers.




U.S. Pat. No. 4,552,178 to Olsson discloses a variable fluid flow restricting throttle device in which a pair of members are rotatably connected in a fluid-tight relationship and each of which includes a plurality of fluid flow openings. The members may be rotated to selectively align the fluid flow openings to create varying flow paths of varying diameters.




U.S. Pat. No. 5,061,406 to Cheng discloses an apparatus for in-line dispersion of a gas in a liquid which includes an adjustable conical mixer to control the flow of a gas/liquid mixture to a venturi device. The venturi device is used to accelerate the mixtures to a supersonic velocity with subsequent deceleration to subsonic velocity to produce shock waves in the mixture.




U.S. Pat. No. 5,230,254 to Blough, Jr. et al discloses a fluid mixing device which includes a mixing chamber and four fluid conduits which join the mixing chamber at predetermined angles to introduce fluids into the mixing chamber and create a rapid vortexing action.




U.S. Pat. No. 5,573,334 to Anderson discloses a method for the turbulent mixing of gases in which a first gas flowing from a first orifice in a tubular housing is directed at a second gas flowing from a second orifice. The two orifices are offset so as to produce a swirling action within the tubular housing.




Although the prior art includes various examples of devices intended to introduce a secondary fluid into a stream of primary fluid, there still remains a need for an apparatus which can both introduce the secondary fluid into the stream of primary fluid and control the flow of secondary fluid in a simple and effective manner.




SUMMARY AND OBJECTS OF THE INVENTION




A fluid inductor apparatus includes a hollow housing having inlet and outlet fluid couplings for insertion of the housing in a fluid conduit which carries a fluid designated as the primary fluid. An adjustment knob is rotationally mounted on an upper panel of the housing, the upper panel including an inlet tube for the introduction of a fluid which is designated as the secondary fluid. The inlet tube communicates with a hollow wedge member which is disposed in the hollow housing. The wedge member has a diamond shape of four side panels which are connected by hinges, thereby facilitating adjustment of the angles formed by the side panels.




The adjustment knob includes a plate with a spiral groove. A pin projecting from a motion transmission plate which has a V-shaped slot moves along the spiral groove and moves the motion transmission plate. A pair of oppositely disposed side panels on the wedge member includes guide pins which project through slots in a guide plate and the motion transmission plate. Rotation of the adjustment knob causes the wedge member to expand and contract in width.




A pair of side panels of the wedge member include a plurality of holes and secondary fluid is drawn into at least one wedge member and then drawn through the holes in the side panels and then drawn into the stream of primary fluid. Rotation of this adjustment knob changes the dimensions of the wedge member thereby varying the venturi effect caused by the wedge member and consequently controlling the flow of secondary fluid from the wedge member.




The present invention also includes a method of inducing a liquid into a flowing stream of another liquid by moving a primary liquid through a flow tube and interposing a distribution member in the flow tube for having its geometry varied to produce a low pressure area at a downstream side of the distribution member. A secondary liquid is introduced into the distribution member and drawn through passages of the distribution member toward the downstream section of the member by the low pressure created from the positioning and shaping of the distribution member with respect to the primary fluid flow.




The present invention also includes a system for adjusting and controlling the combining of first and second fluids at the fluid inductor apparatus according to the present invention.




The system includes a sensor downstream of the fluid inductor apparatus for sensing a specific parameter, such as the blend of the fluids combined by the fluid inductor apparatus, and generating a signal to adjust the fluid inductor apparatus to provide a mixture having select parameters.




Another embodiment of the system according to the present invention includes a secondary mixing device disposed between the fluid inductor apparatus and the sensor to further achieve desired homogeneity of the fluids admixed in the fluid inductor apparatus.




It is an object of the present invention to provide a flow inductor apparatus which draws fluid into a main stream of fluid.




Another object of the present invention is to provide a flow inductor apparatus which utilizes a venturi effect to draw fluid into a main stream.




Another object of the present invention is to provide a flow inductor apparatus which is capable of varying the venturi effect produced by a diamond shaped wedge placed in the main stream.




Another object of the present invention is to provide a flow inductor apparatus which incorporates a flexible member to vary the venturi effect produced in a stream.




Another object of the present invention is to provide a flow inductor apparatus which incorporates a diamond shaped wedge, the profile of which may be precisely varied.




Another object of the present invention which incorporates a venturi generating component which may be adjusted by simply rotating a knob.




Another object of the present invention is to provide a fluid inductor apparatus which incorporates a hollow deformable member to create a venturi effect in primary stream.




Another object of the present invention is to provide a fluid inductor apparatus which has minimum size and bulk.




Another object of the present invention is to provide a fluid inductor apparatus which may be used to draw a secondary fluid into a primary fluid stream in an effective manner.




Another object of the present invention is to provide a fluid inductor apparatus which utilizes a motion transmission plate with a V-shaped slot to control the profile of a diamond shaped wedge.




It is another object of the present invention is to provide a fluid inductor apparatus which utilizes a plurality of holes in a hollow wedge shaped member to induce a secondary fluid into a primary fluid stream.




It is another object of the present invention is to provide a fluid inductor which utilizes a hollow wedge to create a venturi effect in a primary stream and mechanical adjustment means to vary the profile of the hollow wedge which is inserted in the primary stream.




Another object of the present invention is to provide a fluid inductor apparatus which is capable of reliable long term operation.




Another object of the present invention is to provide a fluid inductor apparatus which is both durable and relatively economical to operate.




Another object of the present invention is to provide a fluid inductor apparatus having a relatively small number of component parts which are relatively simple to manufacture resulting in a relatively low overall cost.




It is another object of the present invention to provide a fluid inductor apparatus which is easily maintained and/or repaired in a relatively short period of time, thereby reducing the overall cost of operation.




It is another object of the present invention to provide a fluid inductor apparatus which can be installed in a relatively short period of time.




It is another object of the present invention to provide a system for sensing the mixture of the fluids at the outlet of the fluid inductor apparatus for generating a signal to a control device to adjust the geometric profile of the fluid inductor apparatus to provide a select mixture of the fluids.




It is another object of the present invention to provide a secondary mixing device disposed at the downstream end of the fluid inductor apparatus between said apparatus and the sensor to achieve further homogeneity of the fluids combined at the fluid inductor apparatus.











BRIEF DESCRIPTION OF THE DRAWINGS




For a more complete understanding of the present invention, reference may be had to the following description of exemplary embodiments of the present invention considered in connection with the accompanying drawings, of which:





FIG. 1

is an overall perspective view of a fluid inductor apparatus according to the present invention;





FIG. 2

is a cross-sectional view taken along the line


2





2


of

FIG. 1

;





FIG. 3

is a cross-sectional view taken along the line


3





3


of

FIG. 2

;





FIG. 4

is an exploded view of the apparatus of

FIG. 1

;





FIG. 5A

is a fragmentary cross-sectional view taken along the line


5





5


of

FIG. 3

;





FIG. 5B

is another fragmentary cross-sectional view of the fluid inductor apparatus;





FIG. 6

is a top plan view of a portion of the apparatus shown in

FIG. 4

;





FIG. 7A

is a view of a system according to the present invention having the fluid inductor apparatus; and





FIG. 7B

is a view of another embodiment of a system according to the present invention having the fluid inductor apparatus.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




In

FIG. 1

, a fluid inductor apparatus


10


according to the present invention is shown in a preferred embodiment inserted in a fluid conduit


12


through which there flows a fluid defined as the primary fluid. The direction of the flow of the primary fluid is shown by the arrow


14


.




The apparatus


10


includes a hollow housing


16


which has fluid couplings


18


,


20


, defined as inlet fluid coupling


18


and outlet fluid coupling


20


mounted on end panels


22


,


24


for interposing of the housing


16


in the fluid conduit


12


. A top panel


26


of the housing


16


supports an inlet conduit


28


for a fluid defined as the secondary fluid, and an adjustment knob


30


. The direction of flow of the secondary fluid is shown by arrow


32


in FIG.


1


. The secondary fluid is induced to flow into the housing


16


and mix with the primary fluid in a manner which will be described below.




The top panel


26


is attached to the housing


16


in a conventional fluid tight manner.




The inlet conduit


28


communicates with the secondary fluid in a hollow wedge member


34


which is disposed in the housing


16


as shown in

FIGS. 2-4

. The wedge member


34


has four side panels


36


,


38


,


40


,


42


(


36


-


42


) which are connected by hinges


44


,


46


,


48


,


50


(


44


-


50


) to form a diamond shaped configuration when viewed in plan view. The hinges


44


-


50


allow pivotal motion between adjacent panels


36


-


42


, thereby facilitating adjustment of the dimensions of the wedge member


34


as is indicated by the broken lines


52


in

FIG. 2

under the control of the adjustment knob


30


.




Referring also to

FIGS. 3 and 4

, the adjustment knob


30


is mounted on a shaft


54


which projects through the top panel


26


into the housing


16


to a plate


56


which has a spiral groove


58


. Rotation of the adjustment knob


30


causes rotation of the plate


56


. A pin


60


, which is mounted on a motion transmission plate


62


, rides in the spiral groove


58


. Rotation of the adjustment knob


30


causes motion of the motion transmission plate


62


in the direction shown by the arrow


64


,


66


in FIG.


4


. The motion transmission plate


62


includes slots


68


,


70


which meet in a V-shape.




A guide plate


72


which has slots


74


,


76


forming a V-shape is disposed in the housing below the motion transmission plate


62


. The guide plate


72


has an aperture


78


which allows passage of the inlet conduit


28


to the wedge member


34


.




Oppositely disposed side panels


36


,


38


include guide pins


80


,


82


which project upwardly through the slots


74


,


76


in the guide plate


72


and the slots


68


,


70


in the motion transmission plate


62


.




Rotation of the adjustment knob


30


causes rotation of the plate


56


and the expansion and contraction of the width of the wedge member


34


, thereby causing a precise adjustment in the venturi effect provided by the wedge member


34


in the flow of primary fluid.




Side panels


40


,


42


of the wedge member


34


include a plurality of holes


84


. Secondary fluid is drawn into the wedge member


34


via the inlet conduit


28


. The secondary fluid is induced to flow through the holes


84


of the side panels


40


,


42


and into the stream of primary fluid as indicated by the arrows


86


in FIG.


2


. Rotation of the adjustment knob


30


in the directions shown by the arrows


88


,


90


in

FIG. 4

varies the width of the deformable wedge member


34


, thereby varying the strength of the venturi effect which is created by the introduction of the wedge member


34


in the stream of primary fluid which flows through the conduit


12


. The venturi effect creates an area of relatively lower pressure at the rear of the panels


40


,


42


and control of the venturi effect effectively controls the induction or flow of secondary fluid through the conduit


28


.




As is shown in

FIGS. 4 and 5A

, the slots


68


,


70


in the motion transmission plate


62


form a relatively wider portion


92


of the V-shape which is proximate to the inlet fluid coupling


18


, while the V-shape formed by slots


74


,


76


has a relatively wider portion


94


which is proximate to the outlet fluid coupling


20


. When the motion transmission plate


62


moves in the directions shown by the arrows


64


,


66


of FIGS.


4


,


5


A, the distance between the guide pins


80


,


82


increases and decreases, as controlled by the adjustment knob


30


, thereby changing the width of the wedge member


34


. This change in width of the wedge member


34


controls the strength of the venturi effect created by the wedge member


34


, and the rate of induction of the secondary fluid.




While the motion transmission plate


62


moves in the directions shown by the arrows


64


,


66


as described above, the guide plate


72


remains stationary covering the upper edge


96


of the wedge member


34


, thereby aiding in the introduction of secondary fluid into the wedge member


34


.




Alternatively as shown in

FIG. 5B

, the relatively wider portion


92


of the V-shape formed by slots


68


,


70


may be reversed and disposed proximate to the outlet fluid coupling


20


, while the wider portion


94


of the V-shape formed by slots


74


,


76


is disposed proximate to the inlet fluid coupling


18


. Guide pins


80


,


82


are also now positioned on opposite side panels


40


,


42


, and secondary inlet aperture


78


is on the side closer to inlet


18


.





FIG. 6

shows another embodiment of a wedge member


34


A having side panels


36


A,


38


A,


40


A,


42


A (


36


A-


42


A) hingedly connected to form a diamond shape member. As with the wedge member embodiment


34


described above, each of the side panels


36


A-


42


A can be constructed and arranged with respect to each other to have flexible or living hinge connections


44


A,


46


A,


48


A,


50


A (


44


A-


50


A). With the embodiment


34


A, all of the side panels


36


A-


42


A are hollow with at least one of the side panels


40


A,


42


A having at least one distribution passage


84


A at the outlet or downstream side of the wedge member


34


A. The secondary fluid is introduced into the wedge member


34


A via conduit


28


.




The embodiment


34


A can also be constructed with only one of the side panels


40


A,


42


A being hollow, such side panel being provided with at least one and preferably two distribution passages


84


A.




The wedge members


34


,


34


A can be of one piece construction, or constructed from the side panels


36


-


42


or


36


A-


42


A which are separate and discrete panels.




The wedge members


34


,


34


A are preferably manufactured from a plastic material.





FIG. 7A

shows a system


100


according to the present invention which includes the fluid inductor apparatus


10


of the present invention. The fluid inductor apparatus


10


and its associated features operate in a manner similar to the fluid inductor apparatus discussed above, unless otherwise stated.




In the system


100


, a primary fluid


102


is introduced through a pipe or conduit


104


to an inlet


106


of the fluid inductor apparatus


10


. As the fluid passes through the apertures


84


of the apparatus


10


, the induction process is actuated and a secondary fluid


108


is drawn into the apparatus through the pipe


112


or conduit. The fluid inductor apparatus


10


combines and mixes the fluids


102


,


108


in a manner discussed above with respect to the discussion of the apparatus


10


in

FIGS. 1-6

.




The fluids


102


,


108


are combined and proceed through an outlet


114


of the apparatus


10


, as shown generally at


116


. As the fluid


116


proceeds downstream from the apparatus


10


, it passes through a sensor device


118


exposed to the fluid


116


. The sensor device


118


is mounted in a downstream end of the conduit


104


to sense or measure a particular parameter, such as homogeneity, of the fluid


116


. The sensor device


118


generates a signal


120


representing the fluid


116


characteristics. The signal is transmitted to and received by a controller or processor


122


. The transmission signal


120


can be by hardwire or wirelessly. The controller


122


generates a signal


124


which is received by actuator mechanism


126


. The signal


124


can similarly be transmitted by hardwire or wirelessly.




The mechanism


126


is adapted to mechanically adjust the dimensions or geometric profile of the apparatus


10


to mix the fluids


102


,


108


in the manner desired and selected. That is, the rate of mixing the primary and secondary fluids


102


,


108


can be selectively controlled. The system


100


is able to continuously sense the fluid


116


to determine if it is within acceptable parameters and if not, adjust the dimensions of the hollow wedge member


34


(

FIG. 3

) of the apparatus


10


to induce the secondary fluid into the primary fluid at a rate within the desired parameters to provide the preferred fluid composition


116


.




The mechanism


126


is connected to the apparatus


10


by means of a connecting member


128


and


130


, such as a transmission assembly. This structure


128


,


130


is used in addition to or in lieu of the adjustment knob


30


(FIGS.


1


,


3


) of the apparatus


10


. A seal or gland


132


, provides a water tight connection between the transmission assembly and the apparatus


10


.





FIG. 7B

shows another embodiment of a system


200


according to the present invention which includes the fluid inductor apparatus


10


. The fluid inductor apparatus


10


and its associated features operate in a manner similar to the fluid inductor apparatus discussed above, unless otherwise stated.




In the system


200


, a primary fluid


202


is introduced through a pipe or conduit


204


to an inlet


206


of the fluid inductor apparatus


10


. As the fluid passes through the apparatus


10


, the induction process is actuated and a secondary fluid


208


is drawn into the apparatus through the pipe


212


or conduit. The fluid inductor apparatus


10


combines and mixes the fluids


202


,


208


in a manner discussed above with respect to the discussion of the apparatus


10


in

FIGS. 1-6

.




The fluids


202


,


208


are combined and proceed through an outlet


214


of the apparatus


10


, as shown generally at


216


. As the fluid


216


proceeds downstream from the apparatus


10


, it passes through a sensor device


218


exposed to the fluid


216


. The sensor device


218


is mounted in a downstream end of the conduit


204


to sense or measure a particular parameter, such as homogeneity, of the fluid


216


. The sensor device


218


generates a signal


220


representing the fluid


216


characteristics sensed, which signal is transmitted to and received by a controller or processor


222


. The transmission can be by hardwire or wirelessly. The controller generates a signal


224


which is received by actuator mechanism


226


. The signal


224


can similarly be transmitted by hardwire or wirelessly.




The mechanism


226


is adapted to function similar to the mechanism


126


of

FIG. 7A

, and to coact with the hollow wedge member


34


of the apparatus


10


to mix the fluids


202


,


208


in the manner desired and selected. A seal or gland


232


provides a water tight connection between the transmission assembly and the apparatus


10


.




The system


200


shown in

FIG. 7B

includes a secondary mixer device


234


disposed between the apparatus


10


and the sensor means


218


. The secondary mixer device is in communication with the fluid


216


at the downstream end of the conduit


204


to further achieve homogeneity of the primary and secondary fluids


202


,


208


combined in the fluid inductor apparatus


10


. The secondary mixer


234


employs for example, mechanical means or ultrasound to further mix the fluid


216


to provide the desired uniformity within the fluid


216


. The fluid


216


enters an inlet


236


of the secondary mixing device


234


to be further mixed or acted upon, and then exits an outlet


238


of the device


234


to thereby contact the sensor device


218


in a mixture that will require only a minor amount of adjustment, if any at all, by the control assembly


222


and actuator


226


. By having the fluid


216


in a mixture with the parameters as close as possible to those required, there are then only minor adjustments needed of the geometric profile of the apparatus


10


to induce the secondary fluid into the primary fluid.




The induction rate of the secondary fluid


108


,


208


can be adjusted as necessary to achieve a resulting fluid composition


116


,


216


.




It will be understood that the embodiments described herein are merely exemplary and that a person skilled in the art may make many variations and modifications without departing from the spirit and scope of the invention. All such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.



Claims
  • 1. A fluid inductor system comprising:a housing comprising: a first inlet for a first fluid flow, a second inlet for a second fluid flow, a downstream outlet for an outlet flow; fluid inductor means disposed in said housing in communication with said first and second inlets and said downstream outlet, said fluid inductor means activable to induce said second fluid into said first fluid to provide a select fluid composition; sensor means in communication with said outlet flow for sensing fluid composition of said outlet flow and generating a signal representing said fluid composition; and control means in communication with said sensor means and said fluid inductor means for receiving said signal and controlling actuation of said fluid inductor means to provide said fluid composition.
  • 2. The system according to claim 1, further comprising:mixing means in communication with said outlet flow between said downstream outlet and said sensor means for mixing said outlet flow for being sensed by said sensing means.
  • 3. The system according to claim 2, wherein the mixing means is selected from the group consisting of mechanical mixers and ultrasound mixers.
  • 4. The system according to claim 1, wherein said fluid inductor means comprises a hollow wedge shaped member.
  • 5. The system according to claim 1, further comprising:transmission means interconnecting said control means and said fluid inductor means for activating said fluid inductor means.
  • 6. The system according to claim 1, wherein said fluid inductor means comprises:an adjustable hollow member disposed in said housing between said first inlet, said second inlet and said downstream outlet, and having a plurality of holes formed in said adjustable hollow member proximate to said downstream outlet.
  • 7. A fluid inductor system comprising:a housing comprising: primary fluid inlet means; primary fluid outlet means; secondary fluid inlet means; hollow inductor means disposed in said housing between said primary fluid inlet means, primary fluid outlet means and secondary fluid inlet means, said hollow inductor means having a plurality of holes formed therein proximate to said primary fluid outlet means; sensor means exposed to said primary fluid outlet means for sensing fluid at said primary fluid outlet means and generating a signal representing said outlet fluid; and control means in communication with said sensor means and said hollow inductor means, said control means adapted to receive said sensor signal and generate a control signal to control the shape of said hollow inductor means to induce secondary fluid to flow into said primary fluid at said hollow inductor means.
  • 8. A method of controlling introduction of one liquid into another liquid, the method comprising the steps of:moving a first fluid stream through a flow path; interposing a hollow distribution member in said flow path to provide a venturi effect creating a low pressure area on a downstream side of the distribution member; adjusting the shape of the distribution member in the flow path to effect the low pressure region in the flow path downstream of the distribution member; introducing a second fluid into the distribution member; inducing said second fluid through at least one passage in the distribution member to the downstream side of the distribution member by the low pressure created from the venturi effect; sensing a downstream fluid exiting the distribution member; generating a signal representing said downstream fluid; and monitoring said signal for determining adjustment of said distribution member.
  • 9. The method according to claim 8, further comprising the step of:mixing the downstream fluid after said step of inducing said second fluid.
CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation-in-part of U.S. Ser. No. 09/176,547 filed Oct. 21, 1998 and issued as U.S. Pat. No. 6,170,978, Jan. 9, 2001.

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Continuation in Parts (1)
Number Date Country
Parent 09/176547 Oct 1998 US
Child 09/756147 US