Multiple chemical product eductive dispenser

Information

  • Patent Grant
  • 6655401
  • Patent Number
    6,655,401
  • Date Filed
    Tuesday, September 25, 2001
    23 years ago
  • Date Issued
    Tuesday, December 2, 2003
    21 years ago
Abstract
A dispenser selectively mixes one or more chemical fluids into a motive fluid such as water by using diverting motive fluid to one or more channels formed in an eductor body, at least one of the channels being an eductor. When the motive fluid passes through the eductor, a selected chemical fluid is eductively drawn into the venturi of the eductor, producing a mixed fluid having a desired total flow rate and dilution ratio. Additional dilution ratios, flow rates, and chemical fluids are selectable by diverting motive fluid to another channel or combinations of channels. Carry-over of chemical fluid between dispensing is avoided by diverting the motive fluid rather than by diverting the concentrated chemical fluid.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




This invention relates to dispensers and more particularly to a chemical product selection and venturi eductor device for selectively dispensing and mixing, at a corresponding dilution ratio and total fluid flow rate, one of a plurality of fluids with another fluid.




2. Prior Art




Selector valves typically allow an operator to select and dispense one particular chemical fluid at a time, while closing off access to all of the other fluid sources available for selection. One such prior selector valve typically includes a static body having several inlet ports and one outlet port and a rotatable valve core with passages to allow selective connection of a selected inlet port with the outlet port. Sealing of the non-selected inlet ports is provided by a spring loaded, O-ring sealed plunger carried in the rotatable core and bearing against the face of the static body. While selector valves of this type allow for selective connection and dispensing of a plurality of fluids, they have several inherent disadvantages.




One problem associated with selector valves of this type is the ability to efficiently change over from one selected input chemical fluid to another. A residual volume of the prior chemical in many systems of this type must be purged prior to inputting a second selected chemical fluid. Purging the system is very detrimental in that it requires delays in the operation and diminishes the accuracy of the volume and timing of the mixing of the fluids. Because of the distance and the geometry of the path the selected fluid must travel within the selector valve system, the system may contain a significant amount of residual chemical after the user has selected a new inlet port, thereby requiring the user to spend time purging the line.




A contributing factor to the problem of residual fluids in the selector valve is turbulent flow of the fluids through the selector valve. Specifically, the cause of turbulent flow in the selected fluid flow path is commonly stagnation points or blind spots which are typically found at the juncture between mating components. These areas create turbulent flow of the fluid through the selector valve and minimize the ability to effectively purge the valve and flush the residual chemicals. Additionally, turbulent flow through the selector valve retards the fluid flow and requires greater pressures and timing problems for the selected input fluid sources and responsiveness of the selector valve and connected system components.




Two solutions to some of these identified problems are disclosed in U.S. Pat. Nos. 5,377,718 and 5,653,261 which are assigned to the assignee of the present invention. The systems of these patents reduce the amount of carry-over, or residual fluid, retained in the selector valve between dispensing selections by streamlining and reducing the volume of passages that retain residual fluid. Thus, in the illustrative embodiments contained therein, carry-over of less than 0.4 cc and less than 0.1 cc, respectively, are achieved.




While the systems disclosed in U.S. Pat. Nos. 5,377,718 and 5,653,261 solved a number of problems associated with prior selector valves, the systems were directed to reducing the amount of carry-over, and not to eliminating carry-over in the system. While many applications benefitted from the relatively small amount of carry-over, other applications were not suitable.




One specific prior art system avoiding chemical carryover is shown in FIG.


1


. The dispensing system


10


uses two ball valves


12


,


14


, each directing a motive fluid, typically received from a pressurized water supply at a water inlet


16


, to a respective eductor


18


,


20


. Thus, each selector valve


12


,


14


does not direct or retain a chemical fluid. Instead, each chemical fluid is eductively drawn from a respective chemical fluid reservoir


22


,


24


into the corresponding eductor


18


,


20


downstream of the selector valve


12


,


14


, respectively, in response to the motive fluid. Mixed fluid from each eductor


18


,


20


is dispensed from a common outlet


26


. A third ball valve


28


supplies bypass water directly to the outlet


26


for purposes such as achieving a greater dilution, rinsing a hose (not shown) connected to the outlet


26


, and rinsing articles (not shown).




While the dispensing system


10


efficiently mixes a number of chemical fluids for use from a single dispenser, further improvements are desired. For example, selecting a particular mixture requires positioning one or more of several different levers increases the opportunity for human error. In another example, use of several ball valves


12


,


14


,


28


increases the cost for selecting a chemical fluid, as compared to selector valves, such as disclosed in the above-referenced patents. In addition, a dispensing device be of a large size to position each ball valve and their levers.




Consequently, a significant need exists for a device for selectively mixing one or more of a chemical fluid with a motive fluid that is economic and smaller, yet does not carry-over chemical fluid between dispensing.




SUMMARY OF THE INVENTION




In accordance with principles of the present invention, in a preferred embodiment of the invention, a single selection member diverts a motive fluid to separate channels formed in an eductor body, at least one channel and preferably others being selectively and operatively associated with an eductor for drawing a chemical fluid. Thus, a single device is capable of selecting different mixed fluids without retaining a volume of residual fluid, or carry-over. A dispenser using the device can thus be smaller and more economically manufactured.




Consistent with one aspect of the invention, an apparatus for mixing at least one chemical fluid with a motive fluid has a selector body with a motive fluid passage and an eductor body with at least two fluid channels. Each fluid channel is in fluid communication between the motive fluid passage and a dispensing outlet. At least one fluid channel is an eductor whose venturi creates a low pressure when motive fluid passes through the eductor to draw a chemical fluid. Selecting the mixture of the motive fluid and the chemical fluid is achieved with a selector member that is contained within the motive fluid passage of the selector body to divert motive fluid to one or more of selected fluid channels. The single motive fluid selector member achieves an economy and efficiency over systems requiring a plurality of selector devices. In addition, since the selector member diverts motive fluid rather than a chemical fluid, carry-over of chemical fluids between dispensing selections is avoided.




In another aspect of the invention, a dispenser includes an apparatus with two eductors in the eductor body for mixing one of two chemical fluids, each supplied from a respective reservoir with a motive fluid; or alternatively for mixing the source chemical fluid from one or more sources but supplied at different flow rates. Also, different dilution rates may be produced by varying the flow rate of the motive fluid into the eductors. The selector member is positioned to divert motive fluid to at least one of the eductors to dispense the desired mixture.




Consistent with yet a further aspect of the invention, a method of mixing chemical fluids into a motive fluid without a carry-over of a previously selected chemical fluid includes the steps of (1) coupling a first supply of a chemical fluid to a venturi of a first eductor, (2) coupling a second supply of a chemical fluid to a venturi of a second eductor, (3) positioning a selector member to first position to divert the motive fluid to an inlet of the first eductor to dispense a first mixture, and (4) positioning the selector member to a second position to divert the motive fluid to an inlet of the second eductor to dispense a second mixture.




In short, prior art dispensing apparatus selected chemical sources by valves in the chemical lines. This invention contemplates a plurality of chemical eductors that are operated by a single valve in the motive fluid line diverting motive fluid to a selected eductor. Moreover, the motive fluid passage can be diverted to one or more chemical fluid channels connected to the same source to vary the dilution ratio of mixed fluid to be dispensed.




The above and other objects and advantages of the present invention shall be made apparent from the accompanying drawings and the description thereof.











BRIEF DESCRIPTION OF THE DRAWING




The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with a general description of the invention given above, and the detailed description of the embodiments given below, serve to explain the principles of the invention.





FIG. 1

is a cutaway view of a prior art dispensing system using three ball valves and two separate eductors to select between multiple chemical fluids for mixing.





FIG. 2

is a cutaway view of a dispenser consistent with the present invention for selecting between two chemical fluids.





FIG. 3

is a perspective view of a first embodiment of the device shown in

FIG. 2

for selecting and eductively mixing fluids.





FIG. 4

is a cross sectional view along line


4





4


of the device of

FIG. 3

showing fluid flow through the eductor channels.





FIG. 5

is a cross sectional view along line


5





5


of the device of

FIG. 3

showing fluid flow through the bypass channel.





FIG. 6

is a perspective view of a second embodiment of the device shown in

FIG. 2

for selecting and eductively mixing fluids with a selector member comprised of concentric rings, the concentric rings removed for clarity.





FIG. 7

is a perspective view of the device of

FIG. 6

having concentric outer and inner selector rings positioned to select one of four channels.





FIG. 8

is a perspective view of the device of

FIG. 6

having the concentric outer and inner selector rings positioned to select four of four channels.





FIG. 9

is a perspective view of a third embodiment of the device shown in

FIG. 1

for individually selecting channels with push buttons for eductive mixing.





FIG. 10

is a cutaway view of the device of

FIG. 9

showing spools positioned to selectively allow motive fluid to each channel in the eductor body.





FIG. 11

is an exploded view, partially in section, of a fourth embodiment of the device shown in

FIG. 1

for dialing a selector member comprised of a cylinder for selectively allowing motive fluid to a channel in the eductor body.





FIG. 12

is a cutaway view of the device of

FIG. 11

showing the diversion channel, particularly in section, in the cylinder aligned with the bypass channel in eductor body.











DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS




Turning to the Drawings, wherein like numbers denote like parts throughout the several views,

FIG. 2

shows a dispenser


30


and includes a single device


32


for selectively educting one or more chemical fluids for mixing with a motive fluid. Examples of suitable applications for a dispenser


30


include dispensing chemical fluids such as concentrated detergents, glass cleaners, disinfectants, wetting agents, protective polymer polishes, etc., that are diluted to a desired dilution ratio by mixing with a motive fluid of pressurized water. It will be appreciated that other chemical fluids and motive fluids may be used which are consistent with aspects of the invention.




The motive fluid is received at an inlet valve


34


, depicted as a ball valve, and passed through a motive fluid conduit


36


to the device


32


for mixing a selected chemical fluid, drawn respectively from chemical fluid reservoirs


38


,


40


via chemical conduits


42


,


44


. The reservoirs


38


,


40


may be mounted and contained within a cabinet


46


of the dispenser


30


or remotely positioned as shown.




Mixed fluids from the device are emitted from the dispenser through an outlet


48


and a hose


50


connected to the outlet


48


. As will be discussed in greater detail below, the device


32


includes a plurality of pathways for selectively mixing the motive fluid with the chemical fluids, and thus applications consistent with the invention may include an outlet


48


divided into separate conduits for each pathway, as would be known to those skilled in the art.




The device


32


includes a single selection control, depicted as a lever


52


, for selecting the mixing. Consequently, an operator need only move one control, simplifying use of the dispenser


30


and reducing the likelihood for error. In some applications, the selection control includes a position wherein no mixed fluids are emitted from the outlet


48


, and thus the inlet valve


34


may be omitted or not routinely used.





FIGS. 3-5

depict a first embodiment of a selector disk device


60


for the dispenser


30


of FIG.


2


. In particular, the device


60


is integrally formed from separately molded and attached components of a selector body


62


, an eductor body


64


, and an outlet


66


. Between the selector and eductor bodies


62


,


64


, a selector disk


68


and selector seal


70


are contained.




With particular reference to

FIG. 3

, the selector disk


68


is rotated by an externally exposed lever


72


for angularly positioning a disk orifice


74


in the selector disk


68


to one of a plurality of sealed orifices


76


,


77


,


79


under the selector disk


68


, which in turn are respectively registered to one of a plurality of inlets


82


-


84


in the eductor body


64


. The eductor body


64


includes a plurality of fluid channels


88


-


90


that correspond to and include the inlets


82


-


84


. In the illustrative depiction, there is no fourth inlet and no corresponding fluid channel. This allows the selector disk


68


to be positioned to an OFF position at a blind position.




With particular reference to

FIG. 3

, the first fluid channel


88


is illustratively depicted as a first eductor


92


that has a chemical fluid port


94


at the venturi of the eductor


92


for eductively drawing in a first chemical fluid. Typically, a metering tip (not shown) is inserted into the chemical port


94


for controlling the dilution ratio of the first chemical fluid, in coordination with the dimensional sizing of the first eductor


88


. A chemical fluid conduit is connected to the metering tip and is inserted into a reservoir containing the chemical fluid (not shown). Alternatively, the chemical fluid conduit is inserted between the port


94


and the metering tip.




Similarly, the second fluid channel


89


is illustratively depicted as a second eductor


96


that has a chemical port


98


at the venturi of the eductor


96


for eductively drawing in a second chemical fluid. Typically, a metering tip (not shown) is inserted into the chemical port


98


for controlling the dilution ratio of the second chemical fluid, in coordination with the dimensional sizing of the second eductor


96


.




The third fluid channel


90


advantageously illustrates a motive fluid bypass


100


sized for a desired flow rate of the motive fluid without any chemical fluid. It will be appreciated that the eductor body


64


is illustrative only and that various combinations of eductors and bypasses of various sizes may be selected for a specific application to achieve a desired flow rate, dilution ratio, and number of chemical fluids.




With particular reference to

FIG. 5

, a cross-sectional view of the device


60


of

FIG. 3

depicts the fluid flow path with the selector disk


68


blocking motive fluid from entering the eductors


92


,


96


. With particular reference to

FIG. 5

, a cross-sectional view of the device


60


of

FIG. 3

depicts the fluid flow path with the disk orifice


74


angularly aligned to divert motive fluid through the motive fluid bypass


100


. In

FIGS. 4

,


5


the flow path through the device


60


begins with motive fluid passing through a motive fluid passage


102


formed in the selector body


62


. The fluid flow is exposed to an upstream face


104


of the selector disk and passes through the disk orifice


74


into the eductor body


64


. More particularly, in the illustrative depiction, the fluid flow passes into the third fluid channel


90


, i.e., the motive fluid bypass


100


. As shown in

FIGS. 5 and 6

, fluid flow is emitted from the eductor body at outlets


106


-


108


, which are respectively part of the fluid channels


88


-


90


. The emitted fluid flow is collected in the outlet


66


for dispensing through a hose (not shown in FIGS.


3


-


7


).





FIGS. 6-8

depict a second embodiment of a device


120


for the dispenser


30


of

FIG. 2

that employs a concentric disk selection member


122


for diverting motive fluid. In the illustrative depiction, an eductor body


124


is similar to the previously described eductor body of

FIGS. 3-5

, other than having four fluid channels


126


-


129


rather than the previously described three. Thus, the device


120


does not have an OFF position. Instead, the device


120


has a selection member


122


capable of simultaneously selecting one, two, three or four fluid channels


126


-


129


. Thereby, the device


120


is capable of mixing fluids to achieve different dilution ratios of the same chemical fluid or to simultaneously combine two or more chemical fluids with a motive fluid.




The combinations are selectable by radially elongated inlets


132


-


135


to the respective fluid channels


126


-


129


. Then, an outer concentric selector disk


138


, rotatably contained within the device


120


, has an angularly elongated orifice


140


that can be angularly positioned to divert motive fluid to one or two inlets


132


-


135


. Simultaneously, an inner concentric selector disk


142


, rotatably constrained with the outer concentric selector disk


138


, has an angularly elongated orifice


144


that can be angularly positioned to divert motive fluids to one or two inlets


132


-


135


.




For instance, as illustrated in

FIG. 7

, each concentric selector disk


138


,


142


are rotated to only expose one inlet


132


, thus only one fluid channel


126


is selected. By contrast, as illustrated in

FIG. 8

, outer concentric selector disk


138


is angularly positioned to expose inlets


132


,


135


, thereby selecting fluid channels


126


,


129


. Inner concentric disk


142


is angularly positioned to expose inlets


134


,


133


, thereby selecting fluid channels


128


,


127


.





FIGS. 9

,


10


depict a third embodiment of a device


150


for the dispenser


30


of

FIG. 2

that uses push button selection member


152


for diverting motive fluid. In the illustrative depiction, an eductor body


154


is similar to the previously described eductor bodies, except having a fluid channel


156


that is surrounded by four other fluid channels


157


-


160


. A selector body


162


includes a motive fluid passage


164


that separates into vertically elongated inlets


166


-


170


, each corresponding and vertically aligned with an assigned fluid channel


156


-


160


. The selection member


152


traverses a plane that intersects or blocks each inlet


166


-


170


. In particular, the selection member


152


includes a plurality of selection spools or lands


172


-


176


, each traversing within a spool cavity


178


-


182


, as shown in FIG.


10


. Each land


172


-


176


includes a recessed portion


184


-


188


registered to align with the respective inlet


166


-


170


as the spool


172


-


176


traverses through the respective spool cavity


178


-


182


.





FIGS. 11-12

depict a fourth embodiment of a device


200


for the dispenser


30


of

FIG. 2

that uses a cylindrical selection member


202


for diverting motive fluid. In the illustrative depiction, an eductor body


204


is similar to the previously described eductor body of

FIGS. 9-10

. The selection member


202


differs in that its cylindrical outer diameter


206


is received within a cylindrical cavity


208


in a selection block


210


. Along an inner diameter


212


of the cylindrical cavity


208


, an opening


214


provides motive fluid and a plurality of inlets


216


-


220


direct motive fluid to respective fluid channels


222


-


226


. The cylindrical selection member


202


includes a cylinder passage


228


that communicates between two portions of its outer diameter


206


to put the opening


214


into fluid communication with at least one of the inlets


216


-


220


. For instance, as depicted in

FIG. 12

, the cylinder passage


228


has an angularly wide portion


230


that allows communication with the opening


214


when the cylindrical selection member


202


is at various angular positions. An angularly narrow portion


232


of the cylinder passage


228


that selectively aligns with one of the inlets


216


-


220


, which are thus angularly spaced in the illustrative embodiment to select one at a time.




In use, a dispenser


30


mixes a selected chemical fluid when an operator positions a selection member, such as a selector disk


68


, concentric disk selection member


122


, push button selection member


152


, and a cylindrical selection member


202


. Thereby, the device


32


diverts motive fluid to one or more fluid channels, such as to the first eductor


92


that draws a first chemical fluid for mixing, to the second eductor


96


that draws a second chemical fluid for mixing, or to the motive fluid bypass


100


. The selected fluids are then dispensed through an outlet


48


for uses, such as washing or for filling portable dispensing articles, such as spray bottles.




By virtue of the foregoing, a dispenser


30


is provided of reduced volume and reduced number of parts, especially when the plurality of fluid channels are formed within a unitary eductor body


64


. Moreover, since the chemical fluids are eductively drawn, a passive device


30


is achieved that requires no active components to draw the chemical fluids, utilizing instead the motive force form the motive fluid (e.g., pressurized water supply). Also, since gravity is not used to direct the chemical fluids to the dispenser


30


, a more flexible positioning and sizing of chemical fluid reservoirs


38


,


40


is available. Yet, with the flexibility of chemical fluid selection, the single device


32


does not suffer from carry-over of one chemical fluid when changing selections.




While the present invention has been illustrated by a description of various embodiments and while these embodiments have been described in considerable detail, it is not the intention of the applicants to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will readily appear to those skilled in the art. The invention in its broader aspects is therefore not limited to the specific details, representative apparatus and method, and illustrative example shown and described. Accordingly, departures may be made from such details without departing from the spirit or scope of applicant's general inventive concept.



Claims
  • 1. A method of mixing chemical fluids into a motive fluid without a carry-over of a previously selected chemical fluid, comprising:coupling a first supply of a chemical fluid to a venturi of a first eductor contained in an eductor housing coupling a second supply of a chemical fluid to a venturi of second eductor contained in said eductor housing: selectively diverting the motive fluid to at least one of an inlet of the first eductor, to dispense a first mixture, and an inlet of the second eductor to dispense a second mixture: and selectively and simultaneously diverting motive fluid to an inlet of a motive fluid bypass and to the inlet of the first eductor to dispense the first mixture at an increased dilution ratio.
  • 2. A method of mixing chemical fluids into a motive fluid without a carry-over of a previously selected chemical fluid, comprising:coupling a first supply of a chemical fluid to a venturi of a first eductor contained in an eductor housing coupling a second supply of a chemical fluid to a venturi of second eductor contained in said eductor housing; selectively diverting the motive fluid to at least one of an inlet of the first eductor, to dispense a first mixture, and an inlet of the second eductor to dispense a second mixture; wherein the first and second supply are coupled to at least one supply of the same chemical fluid, said method including the further step of: selectively diverting the motive fluid to at least one of the first and second eductors.
  • 3. The method of claim 1 including dispensing said motive fluid and the first mixture through a common outlet chamber.
  • 4. The method of claim 2 including selectively dispensing the first and second mixtures through discrete, separate outlets.
  • 5. The method of claim 2 including a coupling of the motive fluid at different flow rates to at least one of said first and second eductors.
  • 6. The method of claim 2 including diverting motive fluid simultaneously to said first and second eductors.
  • 7. A proportioner for operably dispensing mixtures of motive fluid and chemicals, said proportioner having a plurality of eductors respectively operably connected to a plurality of respective chemical sources, said proportioner comprising:a selector valve housing; a common outlet chamber; an eductor housing having an inlet end and an outlet end; said eductor housing defining said plurality of eductors; said eductor housing operably coupled at an inlet end to said selector valve housing and operably coupled at an opposite end to said common outlet chamber; said plurality of eductors opening at discharge ends thereof into said common outlet chamber; and said eductor housing separating and spacing apart said selector valve housing from said common outlet chamber with said selector valve housing and said common outlet chamber mounted on said respective inlet and opposite ends of said eductor housing.
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Entry
Auto-Chlor System “Automatic Dispensing Diverter Valve” 2 pg brochure, dated Feb. 1996, Memphis Tennessee.