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1. Technical Field
This invention relates generally to apparatus employed in the mixing of chemical concentrate with a diluting liquid. More particularly, it relates to an eductor for drawing chemical concentrate from a container and into the diluting liquid wherein the reduced pressure in the eductor can be easily adjusted.
2. Background Art
The use of eductors for mixing chemical concentrates into a stream of liquid to provide a diluted solution is well known. For example, see U.S. Pat. No. 5,927,338 and No. 6,279,598 issued to S.C. Johnson Commercial Markets, Inc., which teachings are incorporated herein by reference.
Eductors without an air gap are known. One is described in U.S. Pat. No. 6,240,983.
Certain advances in technologies and changes in regulatory communities have given rise to non-air gap means of backflow prevention. One of the new backflow prevention methods is to use an elastomer in a critical path in such a manner that if a backsiphonage occurs, the elastomer will seal the path closed, thus preventing backflow. The atmosphere of an enclosed water supply system lends itself well to Herschel-type venturi systems. Vacuum profiles are based on standard inlet lengths, diameters and cone angles, which are proportional to exit throat lengths, diameters and cone angles. To change a vacuum profile requires a redesign of the entire venturi.
The prior art does not provide a non-air gap eductor wherein the vacuum profile can be changed without redesigning the entire venturi.
The objects of certain embodiments of the invention therefore are:
Providing an improved eductor for a mixing and dispensing apparatus.
Providing an improved non-air gap eductor.
Providing an improved non-air gap eductor wherein the vacuum profile can be changed without redesigning the entire unit.
Providing an improved non-air gap eductor of the foregoing type which can be easily retrofitted.
Providing an improved non-air gap eductor of the foregoing type which can be manufactured at minimal cost.
The foregoing objects are accomplished and the shortcomings of the prior art are overcome by the eductor of this invention which in one embodiment includes a body member providing a longitudinal axis. A flow path extends longitudinally through the body member, the flow path defined by a first flow guide and a second flow guide, the second flow guide constructed and arranged to receive liquid from the first flow guide. A closed back flow prevention member is operatively associated with the first flow guide. A venturi tube is positioned in the flow path for receiving liquid from the second flow guide, the second flow guide and the venturi tube are connected by a passage portion. There is an opening in the passage, the opening is constructed and arranged to produce a desired vacuum in the venturi tube. At least one channel is provided laterally to the longitudinal axis for flowing a liquid concentrate into the venturi tube. The flow path further includes a discharge passage extending from the venturi tube to the outside of the body member.
In one aspect the channel includes a check valve and there are present two lateral channels.
In another embodiment the eductor includes a body member providing a longitudinal axis. A flow path extends longitudinally through the body member, the flow path defined by a first flow guide and a second flow guide, the second flow guide constructed and arranged to receive liquid from the first flow guide. A closed backflow prevention member is operatively associated with the first flow guide. A venturi tube is positioned in the flow path for receiving liquid from the second flow guide, the second flow guide and the venturi tube are connected by a passage portion. There is an opening in the passage. The second flow guide is defined by a tubular portion extending over the opening in the passage. At least one channel is provided laterally to the longitudinal axis for flowing a liquid concentrate into the venturi tube. The flow path further including a discharge passage extending from the venturi tube to the outside of the body member. The extension of the tubular portion over the opening in the passage is designed to afford a desired vacuum profile.
In still another embodiment, the eductor includes a body member providing a longitudinal axis. A flow path extends longitudinally through the body member, the flow path defined by a first flow guide and a second flow guide, the second flow guide constructed and arranged to receive liquid from the first flow guide. A closed back flow prevention member is operatively associated with the first flow guide. A venturi tube is positioned in the flow path for receiving liquid from the second flow guide, the first flow guide and the second flow guide positioned in a spaced relationship so as to divert some of the liquid from the venturi tube to produce a desired vacuum in the venturi tube. At least one channel lateral to the longitudinal axis for flowing a liquid concentrate into the venturi tube. The flow path further including a discharge passage extending from the venturi tube to the outside of the body member.
In yet another aspect there is a method of establishing a vacuum profile in a closed back flow prevention eductor which includes modifying the opening in a passage of the eductor.
In another aspect the second flow guide and the tubular portion are in the form of a funnel member.
These and still other objects and advantages of the invention will be apparent from the description which follows. In the detailed description below, a preferred embodiment of the invention will be described in reference to the full scope of the invention. Rather, the invention may be employed in other embodiments.
Referring to
The inlet line 21 of the equipment 11 is connected to a source of water feeding a header 23. Branch pipes 25 are connected to the header 23 and each branch pipe 25 includes a valve 27 “dedicated” to that pipe 25. When a particular valve 27 is actuated, water flows through the related eductor 10 and mixes a concentrated liquid 17 with such water to form a dilute solution. Each mixed dilute solution is dispensed through a separate tube 29. The amount of concentrate introduced to the eductor 10 can be controlled by the valves 32.
As seen in
As shown in
An outlet passage 61 communicates with a funnel member 64 or first flow guide seated in the conical section 63. A seal 66 is positioned between the outer casing 58 and the conical section 63. A second flow guide 67 is connected to the first flow guide 64 and the second flow guide 67 is connected to venturi tube 65 by a passage portion 69 provided by the funnel portion 80 of the first flow guide 64, the conical section 63, and the second flow guide 67. An opening 70 is provided in the passage portion 69 of the second flow guide 67.
Inlet section 35 is interconnected to the tubular body 33 by the connecting portion 62. It includes input connections 72 and 73 communicating with channels 75 and 76 which in turn communicate with passage 78. A check valve assembly, 74 preferably of the ball check type, is connected to input connection 73. It will be seen in
The embodiments 10A, 10B and 10C illustrated in
As best illustrated in
Referring to
As shown in
A better understanding of the eductors 10, 10A, 10B and 10C will be had by a description of their operation. Referring first to eductor 10, and
The purpose of ball check valve assembly 74 is to serve as a primer for the vacuum in passage 76 and keep prime on the container 15. It also prevents pressurized water from source to contaminate concentrate to chemical from inlet 73.
An important aspect of eductor 10 is the positioning of funnel portion 80 in conjunction with opening 70. This controls the amount of water flowing through the venturi tube 65 and accordingly, the amount of negative pressure created therein. It will be appreciated that the greater the extension of the funnel stem over the opening 70, the greater the volume of water will flow into the venturi tube 65, and the greater the negative pressure. Diverted water passes through the opening 70 and forms a secondary stream which passes into the chamber 68 and subsequently into outlet port 71, whereafter it is combined with the stream of water and chemical concentrate exiting from passage 78. This concentric flow of the secondary stream and the primary stream through the venturi tube 65 is illustrated in U.S. Pat. No. 5,927,338. It is also described in conjunction with eductor 10B in
Eductors 10A and 10B function in substantially the same manner as described for eductor 10. Instead of funnel stem 80 covering a portion of the opening 70, the openings 70A and 70B are designed with specific dimensions to direct a predetermined amount of water away from the venturi tubes 65A and 65B and thus effect a desired vacuum.
The eductor 10C shown in
The siphon-breaking air gap provided by barrel 50 and resilient sleeve 56 operates in the manner described in the previously referred to PCT Application No. PCT/US03/08428. As water flows through fluid outlets 54, it will expand sleeve 56 and water will flow between the sleeve and barrel 50 into funnel member 64 and ultimately to venturi tube 65. When there is no flow of water from the water supply 21 and 25, the resilient sleeve 56 contracts and fits lightly around the barrel 50 to prevent any reverse flow of water. If a siphon action occurs in the water lines 21 and 25, such as when there is a sudden drop in pressure of the main water supply, the resilient sleeve 56 is already sealed against the barrel 50, as already discussed. Fluid instead passes into the space between the sleeve 56 and the outer casing 58 and exits through the vents 60.
It will then be seen that there is now provided an eductor wherein the vacuum profile can be changed without redesigning the entire venturi.
The eductors 10 and 10A have been shown with two inlet ports or connections 72 and 73. If desired, only one could be used as shown in conjunction with eductor 10B. In that instance, the other would be plugged. Alternatively, the inlet connections can be connected to two containers 15 each with the same liquid chemical concentrate or, alternatively, with different chemical concentrate. Ribs 43A, 44A and inlet section 35A are shown as one piece and outer casing 58 as another. If desired, these could be molded from a suitable plastic material as one piece as indicated in