Note: Descriptions are shown in the official language in which they were submitted.
CA 02465154 2004-05-14
D T w P L
BACKGROUND OF THE INVENTION
FiP,~.d of the 2nvention
This invention relates generally to a dilution
dispenser and more particularly to a dilution dispenser
which has a product lock-out and also a dilution
dispenser.
t7a~r~rj.b7~lon of t'-he.~i.Or Ar't
Dilution apparatus using an «.spirator, to
dilute a liquid concentrate with a liquid diluent to
form a use solution, have been used for many years. The
first such systems were ad hoc, loose assemblies of
tubing, connections, aspirators, etc. The typical prior
art diluting station comprises a large reservoir of
concentrate, a source of diluent, typical service water,
and a receiving container for the dilute use solution.
Such a dilution apparatus is operated by passing service
water or other aqueous stream through the aspirator
containing a venturi. A venturi draws the liquid
concentrate from the bulk into contact with the aqueous
diluent stream, mixes the diluent and concentrate
forming a use solution which is then transferred to a
use solution container. The configuration of such a
dilution apparatus has taken a large variety of
embodiments. Large numbers of embodiments of
concentrate containers, transfer mechanism, aspirator
control means, use solution containers and various
combinations of these elements have been attempted in
the past.
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In the past, the prior art dilution systems
have a hose or conduit at the end of the venturi for the
dispensing of the use solution. This conduit is simply
placed inside of the bottle or container to receive the
S use solution. When a plurality of dispensers are used,
for a plurality of chemicals, there is no control or
mechanism to prevent a first chemical being placed in a
bottle which was designed and labeled for a second
chemical.
Still further, when activating the dispenser,
it is often necessary to place the conduit in the bottle
and then, with the other hand, activate the dispenser.
There are prior art dispensers which are activated by
means of pressing the battle backward in the same
i5 direction as is necessary to push the switch which
activates the dispenser. However, it is often more
convenient from a design point to have the activation
button move in one direction and the movement of the
bottle in another direction. However, under prior art
24 devices, it is not possible to have the movement of the
bottle in one direction activate the switch in another
direction.
Accordingly a substantial need exists for a
new versatile diluting apparatus and diluting stations
25 having one or more diluting apparatus. Such stations
ideally will permit the dispensing of a variety of
chemicals into corresponding keyed bottles to make
certain that the correct use solution is dispensed into
the correct bottle. Further, there is a substantial
30 need for a diluting apparatus wherein simple movement of
the bottle in a first direction into the diluting
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an
apparatus will activate a switch, which moves in a second
direction to begin the dispensing of the use solution.
According to the present invention, there is
provided a dispensing apparatus for supplying a liquid to a
bottle having a neck with a geometric cross-sectional
configuration. This dispensing apparatus includes a housing
having an interior cavity and an exit aperture. A
dispensing mechanism is positioned in the housing. A lock-
out member is operatively connected to the exit aperture.
The lock-out member has an opening, a cross-section of
which has a geometric configuration matching the cross-
sectional configuration of the neck of the bottle, wherein
necks of bottles of different geometric cross-sectional
configurations can not enter the exit.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a perspective view of the
dispensing apparatus of the present invention;
Figure 2 is a left side elevational view of
the dispenser shown in Figure 2, with the housing shown
in phantom;
Figure 3 is a front elevational view of the
dispenser shown in Figure 1 with the housing removed and
also showing additional dispensers in phantom;
Figure 4 is an enlarged perspective view of
the bracket and slide actuator shown in Figure 2;
Figure 5 is one embodiment of a lock-out
member for use with the present invention;
Figure & is a second embodiment of a lock-out
member for use with the present invention;
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Figure 7 is a third embodiment of a lock-out
member for use with the present invention;
Figure 8 is an enlarged perspective view of
the bottom portion of the dispenser in Figure 1 and
showing-a lock-out member in an exploded position;
Figure 9 is a view taken generally along the
lines 9-9 showing only the slide actuator; arid
Figure 10 is a right side e~evational view of
4
the lock-out shown in Figure 7.
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DETAxLED DESCRIPTION OF A PREFERRED EMBODIMENT
The apparatus of the invention for diluting a
liquid concentrate to a dilute liquid use solution
contains an aspirator. Aspirators contain a venturi
device driven by water pressure to draw a concentrate.
The venturi device comprises a nozzle opening associated
with a body of concentrate solution. The velocity of the
diluent through the nozzle causes a reduction in
pressure, draws the concentrate into the aspirator,
generally causing a mixing of the concentrate and diluent
typically at a fixed ratio depending on pressure, tubing
sizes and length. Once diluted and mixed, the dilute use
solution leaves the aspirator through an outlet for the
dilute use solution. The outlet is in liquid
communication with the use solution container. The
aspirator is typically sized and adapted to diluent
pressure that ranges from about 10 to about 60 psig.
Preferably, service water is available in most
municipalities at a pressure of about 20 to 40 psig. The
apparatus of this invention works best at such a
pressure. However, the apparatus can be adapted fox a
variety of water pressures.
The concentrate materials of the invention
include general purpose cleaning and sanitizing
materials, coating compositions and other useful
institutional or industrial liquid concentrates. Such
materials include window cleaners, hand soap, hard
surface cleaners, floor cleaners, sink cleaners, tile
cleaners, drain cleaners and drain openers, glass
3D cleaners, cleaners for food preparation units,
sanitizers, disinfectants, aqueous coating compositions,
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water reducible concentrates, water reducible floor
finishes, aqueous wax dispersions, air fresheners, odor
counteractants, and other similar concentrates that can
be formed as an aqueous solution, an aqueous alcoholic
solution, an aqueous dispersion, an aqueous reducible
solution or dispersion, etc.
The- liquid concentrate materials useful for
dilution to a dilute use solution typically comprise
aqueous solutions, aqueous suspensions, aqueous reducible
concentrates, aqueous alcoholic concentrates, etc., of
cleaning or sanitizing chemicals. The concentrate can
contain about 20 to 90 wt% of active cleaning materials.
The typical viscosity of the liquid concentrates
typically ranges from about 1 to 400 cP. The chemical
Z5 systems can comprise a surfactant based cleaner, an
antimicrobial, a floor finish, etc. The cleaner can be a
generally neutral system, an acid-based system containing
compatible surfactant, cosolvents and other additives or
alkaline systems containing a source of alkalinity,
compatible surfactants, cosolvents, etc.
The apparatus is typically adapted and
configured to dilute a variety of liquid concentrates to
useful dilute use solutions. The cross contamination
should be avoided. Acid cleaners can render basic
cleaners inoperative. Further, the addition of a
chlorine source to an acid can release inappropriate
toxic fumes. A variety of other inappropriate
interactions can occur resulting ultimately in a use
solution that is not appropriate for its intended
purpose.
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There is generally disclosed at 10 an apparatus
for diluting a liquid concentrate with a liquid diluent
to form a dilute use solution for dispensing into a
bottle. The dispensing apparatus 10 includes a housing
5 20 which includes a cover 21 and a base 31. The cover 21
and base 31 may be formed from any suitable material such
as a suitable molded plastic. The cover 21 is secured to
the base 31 by a suitable means such as screws 22. The
cover has two access openings 23 on its side. As shown
10 in Figure 1, only one access opening 23 is shown.
However, as will be described more fully hereafter, a
similar access opening is positioned on the opposite side
of the cover 2l to allow access for the diluent. Formed
at the bottom of the cover 21 is an opening 24. The
15 opening 24 is best seen in Figure 8. The bottom of the
housing 20 has a first surface 25 which, when mounted, is
at a slight incline to the horizontal. A second surface
26, in which the hole 24 is formed, is generally
horizontal when the dispenser 10 is mounted. A ledge 27
20 is formed between the two surfaces 25 and 26. The ledge
27 has a rectangular slot 27a formed therein. A screw
opening 26a is formed in the second surface 26. This
structure forms the basis for mounting of various lock-
out members.
25 Several embodiments of lock-out members are
shown. Figure 5 is lock-out member 100, Figure 6 is
lockout member 200, Figure 7 is lock-out member 300.
Referring to Figures 7, 8, and 10, lock-out member 300
will be described in more detail. Lock-out member 300
30 has a generally planar surface 301 in which an aperture
302 is formed. The surface 301 has a tab 303 and a screw
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opening 304. The tab 303 is inserted into the slot 27a
and a screw 305 is inserted through the screw opening 34
and fastened into the screw opening 26a to secure the
lock--out member 300 in the housing 20. The lock-out
member 300 has a collar 306. The collar 306 extends
inward into the cavity inside of the housing 20. The
collar 306 is positioned proximate the member 80d of the
slide actuator 80. As can be seen best in Figure 7, the
aperture 302 has a geometric cross-sectional
configuration of a hexagon. The lock-out member 300 is
designed to be used with a bottle 40, as shown in Figure
1. The bottle 40 is the bottle in which the use solution
is dispensed. The bottle 40 has a generally cylindrical
bottom portion for receiving the use solution. The
bottle 40 has a neck 41 that is smaller diameter than the
cylindrical portion. The neck 4l has a geometric cross-
sectional configuration of a hexagon which matches that
of the lock-out member 300. Therefore, the neck 41 is
able to pass through the aperture 302 as it has a
matching cross-sectional configuration. At the tap of
the neck 41 is a threaded opening 42 for receiving a cap
(not shown).
Figure 5 shows a lock-out member 100 which,
similar to lock-out member 300, has a planar surface 101,
aperture 102, tab 103, screw opening 104. The cross-
sectional configuration of the opening 1.02 is circular
with four inwardly projecting 90° tabs. A collar l06
extends inward and has the same cross-sectional
configuration as the aperture 102.
Figure 6 shows still another example of a lock
out member 200 having a planar surface 201, aperture 202,
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tab 203, and screw opening 204. The geometric cross-
sectional configuration of the aperture 202 is generally
circular with six inwardly projecting tabs. A collar 206
has a similar cross-sectional configuration as the
aperture 202.
Figure 2 discloses a bottle 40' for use with
lock-out 100. The bottle 40' has a generally cylindrical
bottom portion to receive the use solution and a neck
portion 41' which has a cross-sectional geometric
configuration which matches the lock-out 100. It is
understood that various other configurations may be
utilized. An important factor is to design a cross-
sectional configuration which only accepts the geometric
configuration which is similar to the lock-out member's
z5 aperture and does not allow other geometric
configurations, of similar size, t.o pass through. That
is, the bottle 40' would not pass through lock-out member
300 or 200. Similarly, the bottle 40 would not pass
through lock-out members 100 or 200. This is important,
as will be discussed more fully hereafter, far the
prevention of filling a specific bottle with the wrong
chemical use solution.
A drip tray 38 is positioned under the housing
20. The base 31 has a rectangular slot 31a under which a
lip 38a of the drip tray 38 is inserted. This interlock
holds the drip tray 38 in position underneath the housing
20. The drip tray 38 has a base member 38b on which the
bottom of a bottle to be filled may rest. The distance
between the top of the base member 38b and the bottom of
3o the housing 20 is greater than the height of the bottle
in which the use solution will be placed. The bade 31
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has two keyed slots 31b which may be used to mount the
dispensing. apparatus 10 to a suitable mounting surface
such as a wall 99.
A controller or valve 50 is mounted to the base
31 by a means of screws 51. The controller or valve 50
may be any suitable valve such as model 633 B-EL valve
assembly, made by Dema Engineering of St. Louis,
Missouri. The controller 50 has a valve body 52 and side
mounting plates 53. The screws 51 are positioned between
ZO the side mounting plates 53 and the valve body 52. Pipe
plug 54 is operatively connected to the valve body 52.
The valve 50 has an inlet 55 to which a connector 56 is
rnaunted. The inlet 55 and connector 56 exted out of the
housing 20 thru. an opening sized and shaped like access
opening 23. The connector 56 is adapted to receive the
diluent inlet hose 57. Mounted to the valve body 52, is
an activation switch 58. The activation switch 58
includes a body 58a in which a depressable push button
58b is mounted. The button 58b is mounted in the body
58a with a spring which biases the button away from the
valve body to an off position. The valve body 52 has a
threaded outlet 59.
An aspirator 60 is in fluid communication with
the outlet 59. The aspirator 60 may be any suitable
model such as the Air Gap Proportioner 4GPM number
10070400 made by Hydro Systems Company of Cincinatti,
Ohio. In the embodiment shown, the aspirator 60 is an
air gap aspirator. The aspirator 60 has an inlet 61
which is in fluid communication with the outlet 59. The
aspirator 60 includes a venturi which has an inlet that
is in fluid communication with an elbow 69. One end of
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the elbow 69 is connected to the venturi inlet and the
other end has a barbed connection for connecting to a
conduit (not shown) which is in turn placed in a
container of liquid concentrate (not shown) previously
discussed. The aspirator has an outlet 62 that is in
fluid communication with an outlet conduit 63. In this
particular model of the aspirator, the outlet conduit 63
is a dual conduit. The inner conduit dispenses the
dilute use solution and the outer conduit conducts any
spilled diluent into the bottle 40.
A bracket 70, as best shown in Figures 2 and 4,
is secured by means of screws 72 through a hole 71. The
screws 72 connects the bracket 70 to the controller 50.
The bracket has a first side member 73 connected to a
second side member 74 by an intermediate member 75. The
first side member 73 has a rectangular slot 73a and the
second side member 74 has a rectangular slot 74a. The
intermediate member 75 has an aperture 75a through which
the activation switch body 58a is inserted and a
rectangular opening 75b through which a portion of the
aspirator 60 extends. Also provided are access holes
75c. The holes ?5c allow access in order to tighten the
screws 51 which connects the controller 50 to the base
31. The rectangular slot 73a is spaced closer to the
intermediate member 75 than is the rectangular slot 74a.
A slide actuator 80 has a first portion 80a
connecting a second section 80b by an angled (or
inclined) intermediate portion 80c. At the end of the
(first portion 80a is a downwardly depending member 80d.
As shown in Figure 9, this member 80d has a slot 80e
through which the outlet conduit 63 may be inserted. The
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first portion 80a is inserted through the rectangular
slot 73a and the second portion 80b is inserted into the
slot 74a. The bracket 70 is typically made of plastic
and is therefore deformable to allow the second portion
80b to be inserted into this rectangular slot 74a. Two
motion limiting stops 81 are positioned through entxy
holes in the first portion 80a. These stops 81 limit the
linear movement of the slide actuator, as will be
discussed more fully hereafter.
20 Referring to Figure 2, in use, a bottle 40'
having a correspondingly keyed collar 41' to the
appropriate lock-out 100° is placed on the base member
38b of the drip tray 38. In this position, the top of
the bottle is spaced away from the bottom of the housing
20. The conduit 63 is placed inside of the bottle 40'.
Typically, since the conduit 63 extends into the bottle
when it is placed on the base 38a, it is usually
advisable to insert the conduit into the bottle as it is
being positioned under the housing 20 and onto the drip
tray. Then, the bottle 40' is moved upward, as shown by
the phantom lines in Figure 2. This is generally
parallel to a longitudinal axis of the conduit. It is
necessary to orient the neck 41' of the bottle 40° so as
to allow it to pass through the lack-out aperture 102
and make contact with the member 80d of the slide
actuator 80. Then, as the bottle continues to move
upward the slide actuator 80 is moved upward, as shown
by the phantom line in Figure 2.
When the slide actuator is in a first positron
(non-use), the button 58b is fully extended and is under
the second portion 80b. Then, as the slide actuator is
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moved to a second position (use), the inclined portion
80c contacts the button 80b and depresses it downward as
the slide bracket travels in a direction substantially
parallel to the longitudinal axis of the conduit 63.
The motion of the button Bob is in a direction
substantially perpendicular to that of the movement of
the bottle 40'. However, it is understood that other
angled relationships may also be utilized with the
present invention. The angle of the incline is
approximately 30°. zt is preferable that approximately
3/4 inch of the travel of the slide actuator will cause
approximatley 2/2 inch movement of the button. With
this 1/2 inch movement, the button is then depressed and
the dispenser is activated.. That is, the controller 50
then allows a use solution to enter the valve body 52
through its inlet 55. The water then exits the outlet
59 through a nozzle and is sprayed through the venturi
of the aspirator 60. This in turn causes the. liquid
concentrate to be picked up through its inlet 61 from
the liquid concentrate (not shown). It is well known in
the art how a conduit is connected to the barbed end of
the elbow 69 and is placed into a reservoir of liquid
concentrate. Then, the dilute use solution exits the
outlet 62 into the outlet conduit 63 and finally into
the bottle 40'. The stops 81 prevent excessive movement
of the slide actuator and properly positions the slide
actuator.
The lock-outs 100, 200p and 300 are color
coded to their respective bottles. That is, the bottle
which has the same geometric cross-sectional
configuration as the lock-out will have a colored label
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the same color as the lock-out. This will assist the
operator in making certain that they fill the bottle
with the correct use solution.
Figure 3 shows a dispensing system which
includes a plurality of dispensers 10, 10', and 10".
The dispensers 10' and l0" are identical to dispenser
20, with the exception of using a different lock-out
member. When used in a system such as shown in Figure
3, three different liquid concentrates may be dispensed.
Each of the dispensers 10, 10°, and 10" have a different
lock-out member associated therewith. Accordingly,
three bottles, each having a corresponding cross-
sectional configuration as the opening of the lock-outs,
would be used with each dispenser. The bottle which is
in use for dispenser 10', would not be able to enter the
opening of the dispenser 10 or ZO'. Therefore, the
bottle would not be able to activate the wrong dispenser
since it would not be able to move the slide actuator 80
since it would not be abi.e to pass through the opening
of the lock-out.
Another feature of the present invention is
that the lock-outs are replaceable. While it is, of
course, desireable that the correct bottle be used,
there may be certain circumstances where an operator
would run out of one type of bottles. In such a case,
the lock-out may be easily removed by simply removing
the screw and lifting the tab out of the opening. Then,
the entire opening 2~a is available for a bottle to be
inserted to actuate the slide actuator 80.
The above specification, examples and data
provide a complete description of the manufacture and
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use of the composition of the invention. Since many
embodiments of the invention can be made without
departing from the spirit and scope of the invention,
the invention resides in the claims hereinafter
appended.
