Fluid dispenser

A device for mixing and dispensing fluid is disclosed and comprises first and second containers each having a valve for dispensing fluid. The valve is normally biased to a closed position and operable against said bias to an open position. Piston and cylinder elements define a chamber for receiving the fluids. The piston element is movable in response to dispensing of fluid into said chamber. The piston element is operably connected to the valves and exerts a force on the valves to maintain them in an open position. The mixed fluids in the chamber are thereafter dispensed through a handpiece.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to the dispensing of fluids stored under 
pressure, and, more specifically relates to an apparatus and method for 
dispensing of two fluids, mixing the two fluids and applying the mixture. 
Additionally, the present invention relates to a mechanism for maintaining 
a valve of an aerosol container in an open condition once the valve has 
been initially actuated to provide dispensing of substantially all 
contents of the container to be dispensed. 
2. Description of the Prior Art 
It is desirable to dispense fluid from a relatively inexpensive disposable 
package such as an aerosol container or similar pressurized container. In 
some applications, it is desirable to dispense fluids from two or more 
separate containers which contain different fluids. The fluids may be 
designed to react with each other and/or one fluid may be chemically 
unstable or uncompatible with one or more of the other chemicals. One use, 
for example, is in periodontal applications where it is desirable to mix 
two incompatible chemicals as disclosed in U.S. Pat. No. 4,521,403. One 
such device for dispensing fluids from a plurality of containers is 
disclosed in U.S. Pat. No. 3,613,956 to Roger L. McCulloch. The McCulloch 
patent discloses to two aerosol dispensing containers having hollow valve 
stems that are displaceable to discharge fluid under pressure from the 
containers. The mechanism for actuating the valve stems comprises a handle 
that pulls the valve stems inward toward their respective containers to 
actuate the valves. The valves are manually pulled inwardly by a trigger 
which is returned to its original position when it is no longer desired to 
dispense fluid from the aerosol containers. One of the primary 
disadvantages of a system that contains aerosol valves that may be 
repeatedly open and closed is that the fluid in the containers are not 
completely dispensed in one actuation of the valves. Since the pressures 
and the flow rates through the valves may differ from container to 
container depending upon the type of fluid being dispensed, the size of 
the valves, and the pressure in the container, the materials may be mixed 
in undesirable proportions. In addition, if the containers have equal 
pressures, but the flow rate through the respective valves is different, 
the head pressure in the mixing chamber may rise to a level where it 
prevents flow from one of the containers. Thus, the liquids will not be 
mixed in the desired proportions. Thus, it is desirable to provide a 
dispensing device wherein substantially all the fluid from each container 
is dispensed when the valves of the containers are actuated, and wherein 
the valves are locked in an open position. It is also desirable to provide 
a device and method of operation wherein both containers fully dispense 
and build up of pressure in the mixing chamber do not present further 
dispensing from one container. 
In instances where a fluid is being dispensed from a single container or a 
plurality of containers containing fluid under pressure, it is desirable 
to insure that the substantially all of the fluid is expelled from each 
container when its respective valve is actuated. Thus, in prior art 
aerosol dispensing devices, the valve is typically held down either 
manually or by a mechanical locking means which are actuated once the 
valve stem is depressed toward the container. For example, U.S. Pat. No. 
3,887,112 to Bolduc et al, U.S. Pat. No. 2,936,756 to Gabriel; U.S. Pat. 
No. 3,191,808 to Spalazzi et al and U.S. Pat. No. 3,245,586 to Haggit 
disclose mechanisms for maintaining one or more aerosol valves in an open 
condition. 
When the valve is manually maintained in an open position, only one hand of 
the person using the dispensing device is available to manipulate other 
things. Thus, it is an object of the invention to provide a dispensing 
device which maintains the valve in the open position once it is actuated, 
without the need for the person operating the device to apply pressure to 
maintain the valve in its open position. It is also an object of the 
invention to provide a simple mechanism for maintaining one or more 
container valves in an open condition. Additional objects will be apparent 
from the description which follows 
SUMMARY OF THE INVENTION 
In accordance with one aspect of the present invention, a device for mixing 
and dispensing fluid is provided and comprises at least a first and a 
second container each having a valve for dispensing the fluid. Each valve 
is normally biased to a closed position and operable against the bias to 
an open position. A device also includes a mixing chamber for receiving 
the fluids from both containers. The device includes a mechansim for 
actuating both of the valves to dispense fluids into the chamber and such 
mechanism may include a plunger which pushes the containers downwardly to 
force the valves to actuate. Once the valves are actuated, fluid under 
pressure is dispensed into the chamber. A device in accordance with this 
aspect of the invention includes a mechanism responsive to an increase in 
pressure in the mixing chamber for simultaneously maintaining both the 
valves in an open position. In accordance with a preferred embodiment of 
the invention, piston and cylinder elements define the chamber that 
receives the fluid. One of the elements is movable in response to an 
increase in pressure in the chamber and is operably connected to the 
valves to exert a force on the valve to maintain it in an open position 
In accordance with a preferred aspect of the invention, the piston element 
is slidable within the cylinder element and the piston element is movable 
from a rest position toward the upper portion a case which houses the 
piston and the chamber. The piston element includes two passages which 
receive the valves and permit flow through these passageways into the 
chamber. 
In accordance with the above described aspect of this invention, the 
containers are movable reciprocally with respect to the case from an 
initial position toward the piston element. When the containers are moved 
downwardly, the valve stems of the valves are pressed inwardly to open the 
valves and dispense fluid under pressure into the mixing chamber. When the 
pressure in the chamber increases, the piston is forced upwardly and 
maintains the valve in an open position. 
Thus, the above described device is advantageous in that the entire 
contents of the containers is dispensed. Also, after an initial manual 
operation of the plunger to move the containers downwardly, the valves are 
maintained in an open position by the piston element which is forced 
upwardly by the increased pressure in the mixing chamber. Thus, after an 
initial manual actuation, the valves are maintained in an open position 
dispensing fluid into the chamber. The dispensing device includes a 
mechanism for dispensing fluids from the mixing chamber such as a fluid 
transfer line from the chamber to a handpiece which may be manually 
controlled to dispense the mixed fluids. Thus, the increased pressure in 
the head space of the mixing chamber provides the dispensing force for the 
mixture. 
In accordance with another aspect of the invention, the device can include 
a single container and provides a single shot device for dispensing fluid. 
Thus, where it is desirable to dispense all of the fluid from a single 
pressurized container once the container valve is initially actuated, the 
piston element maintains the valve in an open condition. 
In accordance with a preferred aspect of the invention, the device includes 
a case having an upper portion sized and shaped to store at least one 
container and has a lower portion forming the cylinder element. By using 
the case itself to form an integral cylinder element, a multiplicity of 
parts may be avoided and the device is simplified and consists essentially 
of a case having an integral cylinder element, a piston element and two 
valved aeresol containers. Additional features and advantages will be 
described in the detailed description of the invention which follows.

DETAILED DESCRIPTION OF THE DRAWINGS 
Referring to FIGS. 1 and 2 the various components of the device for mixing 
and dispensing fluid is shown. The device comprises a casing 10 including 
an integral cylinder element 12, a piston element 14, two containers 16 
and 18 and a plunger 20. The casing has an upper portion 22 sized and 
shaped to store at least one container. More specifically, the upper 
portion of the casing is sized to receive the pressurized container or 
containers in which the fluid to be dispensed is stored. It may be 
desirable to store and dispense a single fluid, in which case the upper 
portion 22 would be sized to receive a single container. If multiple 
containers are desired for dispensing different fluids, the container is 
shaped to receive such multiple containers. In the case of the device 
shown in FIG. 1, two containers having a generally cylinderical shape are 
used. Thus, the cross-section of the upper portion 22 of the casing has 
the general shape of an oval. The casing has an integral cylinder and 
element 12 sized and shaped to receive the piston element 14. 
Referring in particular to FIG. 2, the piston element 14 comprises a 
cylindrical sleeve 22 having cap 24 at one end thereof. Cap 24 functions 
as a piston sliding with respect to cylinder element 12. The cylinder 
element 12 has an inner diameter 28 which is sized to receive the sleeve 
22 of piston element 14 and provide a fluid seal therebetween. 
For each valve and associated container, the cap 24 includes a passageway 
therein for receiving the valve. In the case of the device shown in FIG. 
2, the cap 24 includes two passageways 30 and 32 which are designed to 
receive valve stems 34 and 36 of containers 18 and 16 respectively. 
The device includes a plunger 20 that is slidably received within the upper 
portion 22. The plunger 20 has two protrusions 38 and 40 that slide 
respectively in guide openings 42 and 44 of the casing 10. The sliding 
movement of the plunger 20 is limited between the position shown in FIG. 2 
and the position shown in FIG. 4. 
The containers 16 and 18 are sealed and capable of withstanding substantial 
internal pressures, and include dispensing valves 46 and 48. Each of the 
valves 46 and 48 are normally biased to a closed position and operable 
against the bias to an open position. Preferably, the valves comprise a 
stem valve. More particularly, valves 46 and 48 include stems 34 and 36 
which are biased to the position shown in FIG. 2 and movable inwardly into 
the container against the bias to the position shown in FIGS. 3 and 4. 
When the stem is in the extended position shown in FIG. 2, the valves 46 
and 48 are closed. When the stem is moved inwardly, fluid is dispensed 
through the stem. Referring to FIG. 2, the valves stems 34 and 36 are in 
abutting relationship with the stop surfaces 50 and 52 on passageways 30 
and 32. 
At the lower end of the mixing chamber, the cylinder wall includes an 
annular groove 56 for receiving the annular terminal edge 57 of piston 
sleeve 22. Thus, in its initial position, the bottom edge piston sleeve 22 
is locked within the annular groove to keep any gas initially dispensed 
into the chamber 58 from leaking into the upper portion 22 of the casing. 
As the chamber 58 begins to fill, the liquid level is maintained above the 
location of seal formed between the piston sleeve 22 and the cylinder 
wall. 
The bottom of chamber 58 includes an outlet 60 connected to a flexible tube 
62 which extends to handpiece 64. The flexible tube is inserted over a nib 
65 into an annular receptacle 66 at the bottom of the device and is 
secured with respect to the casing by a ring 68 which is force fitted into 
annular receptacle 66. The ring forces the tube 62 radially inwardly 
against the nib 65. 
The operation of the device will be described sequentially with reference 
to FIGS. 2 through 5. The casing is held in an upright position as shown 
in FIG. 2 and the handpiece is manually held in a closed position. 
Alternatively, the handpiece could be held in a closed position by a 
mechanical fastener of some type and moved to the open postion when it is 
desired to dispense a mixture of fluids. 
The plunger 20 is pushed downwardly a small distance. Interior face 21 of 
the plunger contacts the upper surface of the containers and pushes the 
containers downwardly. A person actuating the device supplies sufficient 
force to overcome the spring bias on valve stems 36 and 34. As shown in 
FIG. 3, the containers are pushed downwardly thus actuating the valves to 
dispense fluid into chamber 58. The plunger as it moves downwardly not 
only urges the containers downwardly, but also pushes the sleeve 22 
downwardly so that the annular groove 56 engages the edge 57 of the 
sleeve. Thus, gas dispensed into the chamber 58 is prevented from leaking 
by a positive mechanical and frictional seal. 
Once sufficient manual force is placed on the plunger, the valves are 
actuated and dispense the liquid into the chamber as shown in FIG. 4. When 
the pressure in the chamber 58 increases, the piston element 14 is urged 
upwardly against the valve stems 34 and 36 holding the valves open. As 
hand pressure is released from the plunger 20, the plunger moves upwardly 
under the force of the pressure in chamber 58 and under the spring bias of 
valve stems 34 and 36. Once the plunger reaches the position shown in FIG. 
5, the plunger is prevented from further movement by the abuttment of the 
annular flange 38 with the stop surface 70 on guide grooves 44 and 42. The 
piston element 14 continues to move upwardly to the position shown in FIG. 
5 wherein the pressure in the chamber is sufficient to overcome the valve 
bias. The valves are maintained in an open position by the force of the 
piston element. 
It should be understood that the containers are designed such that the 
pressure in the head space of chamber 58 is sufficient to overcome the 
spring bias of stems 34 and 36. Thus, the diameter of the piston, the 
pressure in the head space of the piston after the containers have fully 
dispensed and the spring bias on the valves 32 and 34 are selected so that 
the force of the pressure on the piston element is sufficient to overcome 
the bias of the valves. 
Once the fluids in the two containers are dispensed into the chamber 58, 
the entire casing can be gently agitated to insure complete mixture. After 
the two fluids are fully mixed, a person may dispense the mixture by 
operating the handpiece 64. 
The handpiece will now be described in detail. The handpiece 64 includes a 
body 80 having a hollow cavity 82. The tube 62 is run through the hollow 
cavity 82 to a nozzle 84 which has a narrow tip 86 to permit focused 
dispensing of the fluid mixture. The tubing 62 is preferably made of a 
resilient material which biases the pinching mechanism 88 to the open 
position shown in FIG. 2. The pinching mechanism is secured and preferably 
integrally formed with a lever 90 which is secured at its end 92 to the 
body 80 of the handpiece. The person actuating the handpiece pushes down 
on the lever as indicated by arrow 94 thus forcing the pincher 88 to close 
the resilient tube 62. When finger pressure is released, the resilient 
nature of the tube forces the pincher 88 upwardly and allows passage of 
liquid through the tube to the nozzle 84. In accordance with a preferred 
aspect of the invention, the body 80 includes an elongate slot 110 
extending lengthwise of said body. The slot includes a terminal end 112 at 
the region of the body farthest away from its dispensing end. The 
handpiece includes an end cap 114 secured to one end of the body 80. More 
particularly, the end cap 114 has an inner diameter sized to frictionally 
receive the outer diameter of body 80. Lever 90 is integral with end cap 
114 and extends lengthwise of the body and is aligned with slot 110. The 
lever has an end 116 extending into the cavity 82 and lengthwise past said 
slot terminal end 116 thereby retaining the lever 90 against movement away 
from the body when said lever end 116 contacts said slot terminal end 112. 
It should be understood that the end cap and integral lever 90 are made of 
a resilient polymeric material and are sized so that the resiliency of the 
material urges the lever 90 and therefore the lever end 116 into contact 
with the terminal end of the slot. Thus, the bias of the lever is provided 
by the materials from which the lever and end cap 114 are made, and a 
separate spring or other means for biasing the lever 90 is not required. 
The pinching mechanism 88 which comprises a stud extending inwardly into 
the cavity, permits the flexible tube 62 to be pinched. It should be 
understood that the tube is pinched in various degrees so that not only 
are on and off modes provided, but also the flow rate through the tube can 
be controlled by finger pressure on the lever. Stud 88 has a length 
designed to permit the tube 62 to be in a fully opened position when the 
lever 90 is biased to the position shown in FIG. 2. The stud 88, when the 
lever is moved downwardly, closes flexible tube 62. 
As shown in FIG. 2A and B, the end cap includes a hub 118 inserted into a 
receptacle 120 of end cap. As shown in FIGS. 2A and B, the hub includes an 
end portion 122 extending to the cavity and sized to receive the end of 
flexible tube 62. The hub includes a passage 124 which diverges as it 
extends outwardly. As best shown in FIG. 2B, the cross-sectional area of 
the diverging portion of passage 118 has a cross-sectional shape other 
than circular. More specifically, the diverging portion has a square 
cross-section. When the nozzle 84, which is a small diameter piece of 
metal tubing, is inserted into the passage 118, it is secured in the 
passage by an epoxy filler. Because the cross-sectional area of the 
passageway is other than circular, the nozzle 84 will not rotate within 
the passageway 118. More specifically, an epoxy filler tends to adhere 
extremely well to the metal tubing of the nozzle 84, but will not adhere 
well to the plastic from which the hub 118 is formed. Thus, but for the 
irregular shape, the epoxy would tend to break free from the plastic and 
rotate within the passageway 118. The irregular cross-section and 
preferably a square cross-section, prevents rotation of the solidified 
epoxy thus preventing rotation of the nozzle 84. 
As shown in the drawings, the dispensing device has two major pieces, the 
casing and the handpiece. If desired, the handpiece could be made part of 
the casing to provide essentially a single piece unit. 
Referring to FIG. 2, the fluid in each container includes a liquid 
component 100 and a gaseous propellant component 102. Container 16 has a 
fluid having a liquid component 104 and a gaseous propellant component 
106. By a liquid component, it is meant a liquid, or a liquid containing 
solid materials capable of flowing. In order to fully dispense the liquids 
100 and 104 from their respective containers, the pressure of gases 102 
and 106 must be maintained above the pressure in chamber 58 which is 
initially at atmospheric pressure. 
One example of the use of the device in accordance with the present 
invention is for the mixture of hydrogen peroxide and providone iodine in 
periodontal applications. In such an instance, the container 16 is filled 
with 10 cc of providone iodine and has a pressurized nitrogen head space 
having a pressure of approximately 42 psig. The other container 18 
includes a 10 cc volume of hydrogen peroxide having a 1.5 cc layer of 
butane and having a propellant head space having a pressure of 17 to 20 
psig. 
In accordance with one aspect of the invention, the valve stems 34 and 36 
have different orifice sizes, which, in turn, effect the time it takes for 
the valve to dispense the fluid. In accordance with the example, the stem 
36 has a 0.050 orifice and the stem 34 has a 0.013 orifice. 
The charts in FIGS. 6 through 11 show the pressures of the two containers 
and the chamber 58 over a period of time and the volume of liquid in the 
two containers and the chamber over a period of time. 
Initially, when the plunger is forced downwardly, the providone iodine is 
dispensed into the chamber in approximately two seconds. The hydrogen 
peroxide simultaneously with providone iodine empties into the chamber, 
but this takes approximately 11 seconds. The pressure in the chamber 
increases by the addition of the peroxide to 8 to 10 psig. When the butane 
finally enters the chamber, the pressure therein increases to 25 to 30 
psig. The pressure in the chamber 58 is sufficient to overcome the bias of 
valves 34 and 36. More specifically, the pressure in chamber 58 acts on 
the effective diameter of the piston and the geometry of the device is 
selected so that the pressure on the piston is sufficient to overcome the 
forces provided by the spring bias of valves 34 and 36. 
A device in accordance with the present invention is particularly suitable 
for mixing two or more fluids which are desirably stored separately. In 
one embodiment of the invention, the device provides a single shot 
application. That is, once the device is initially actuated, full 
dispensing of all the components in the containers is insured to provide 
the desired proportional mixture. Moreover, the device is a single shot 
device that is relatively inexpensive to manufacture and that may be 
discarded after a single use. While the device is particularly suitable in 
periodontal applications where it is desirable to mix providone iodine 
with hydrogen peroxide, it is apparent that the device can be used to mix 
components for various other applications. 
It should be understood that although specific embodiments of the invention 
have been described herein in detail, such description is for purposes of 
illustration only and modifications may be made thereto by those skilled 
in the art within the scope of the invention.