Passive venting for pump dispensing device

A manually operated pump dispensing device is provided for dispensing a liquid product. The manually operated pump dispensing device includes a container for storing the liquid product, a dispensing pump and a gas-permeable/liquid-impermeable vent. The container has an interior chamber and an exterior that is exposed to the environment. The dispensing pump is attached to the container in fluid communication with the liquid product. The dispensing pump has a discharge orifice and an actuator. The gas-permeable/liquid-impermeable vent comprises a venting module that includes a membrane and a support frame. The membrane is gas-permeable/liquid-impermeable and is affixed onto the support frame such that the membrane surrounds the support frame. The vent allows for communication between the interior chamber and the environment, thereby passively venting the container.

FIELD OF THE INVENTION 
The present invention relates to pump dispensing devices for use with 
consumer product containers; and more particularly, to such devices which 
allow venting of gases without allowing leakage of the liquid product. 
BACKGROUND OF THE INVENTION 
Manually operated dispensing devices for pumping a liquid from a supply 
container are widely known in the art. Typically manually operated pump 
dispensing devices are provided with at least one vent from the interior 
chamber of the container to the exterior environment in order to allow air 
to enter the container as liquid is drawn from the container through the 
dispensing device in order to prevent either collapse of the container 
from the vacuum created therein or a cessation of the liquid flow, both of 
which are undesirable. One problem associated with most manually operated 
pump dispensing devices is keeping the liquid from leaking out of the 
associated container through the vent during periods of use when the 
container is inverted or as the liquid product is splashed around within 
the container, or even during periods when the user might wish to lay the 
container down or to carry it from one job to another, or even during 
shipment. 
Additionally, certain liquid products, for example, hydrogen peroxide or 
other bleaches as well as carbonated beverages or other liquids which 
cause chemical reactions, can generate gases and this can lead to the 
build up of pressure inside the interior chamber of the container. Without 
a way to vent these gases the container is subjected to severe stress 
which usually causes bulging or stress cracking of the container. Bulging 
refers to the deformation of the container, while stress cracking may 
cause leakage, bursting, or in extreme circumstances an explosion which 
can create a potentially hazardous or detrimental situation. These 
problems are less apparent in thick-walled containers but consideration of 
cost and the desire to minimize usage of material resources, thereby 
reducing the environmental impact, tends to favor use of thin-walled 
containers where possible. Containers for most consumer products which 
include manually operated pump dispensing devices are typically 
thin-walled and are often made of plastic. Thus to avoid these potential 
problems it would be desirable to vent the container on which the manually 
operated pump dispensing device is attached during periods of use as well 
as non-use. 
Various venting mechanisms have attempted to solve one aspect of this 
problem or another. Many of these devices are complex, difficult to make 
and expensive, while still falling short of resolving all of the above 
mentioned concerns. Most manually operated pump dispensing devices provide 
venting mechanisms that require manual operation or some other form of 
user interaction. Typically such venting mechanisms have an open position 
allowing the passage of fluids and a closed position in which the vent is 
entirely closed off preventing the passage of any fluids. In this type of 
venting mechanism the problem of off-gassing is exacerbated when the vent 
is closed. Some other manually operated pump dispensing devices provide 
only one-way venting, for example, when the pressure within the container 
is less than the pressure of the exterior environment, air is permitted to 
enter the container. Still other venting mechanisms are simply open 
passages through which air enters or exits the container. However, this 
latter type of venting mechanism also allows the liquid product to leak 
out of the container when the container is agitated or inverted. 
Consequently, the need exists for a manually operated pump dispensing 
device that allows gases to enter and exit the container housing the 
liquid product, while also preventing the liquid product from leaking from 
the container during periods of use and non-use without the use of complex 
valve systems that are expensive to manufacture. It would also be 
beneficial to provide such a manually operated pump dispensing device that 
vents passively so as not to require any user interaction. 
SUMMARY OF THE INVENTION 
In one embodiment of the invention, a manually operated pump dispensing 
device for dispensing a liquid product is provided. The manually operated 
pump dispensing device comprises a container for storing the liquid 
product. The container has an interior chamber and an exterior exposed to 
the environment. A dispensing pump is attached to the container in fluid 
communication with the liquid product. The dispensing pump has a discharge 
orifice and an actuator. Preferably, the dispensing pump further comprises 
a housing having a reciprocating piston therein and the reciprocating 
piston being moveable between a non-dispensing position and a dispensing 
position. Alternatively, the dispensing pump can comprise a flexible pump. 
The actuator preferably comprises a trigger being attached to the housing 
and connected to the dispensing pump in order to actuate the dispensing 
pump when an operating force is applied to the actuator. The housing has a 
closure for sealingly attaching the housing and the dispensing pump to the 
container. The housing includes an inlet passageway providing fluid 
communication between the liquid product within the interior chamber and 
the dispensing pump and an outlet passageway providing fluid communication 
between the dispensing pump and the discharge orifice. The housing 
preferably has a vent aperture therethrough allowing communication between 
the interior chamber and the environment. A 
gas-permeable/liquid-impermeable vent is also provided. The 
gas-permeable/liquid-impermeable vent further comprises a venting module 
having a membrane and a support frame. The support frame having open 
spaces formed therein. The membrane is substantially 
gas-permeable/liquid-impermeable. The membrane preferably comprises an 
acrylic copolymer which more preferably has a hydrophobic coating of a 
fluoro-monomer which is polymerized onto the membrane using UV light. The 
membrane includes pores having a diameter in the range of from about 0.005 
microns to about 10 microns. The support frame preferably comprises a 
non-woven nylon or a polyethylene terephthalate. The membrane is affixed 
onto the support frame such that the membrane spans the open spaces in the 
support frame. The membrane is preferably cast onto the support frame. The 
venting module is preferably attached by the support frame to the housing, 
over the vent aperture. The venting module being substantially impermeable 
to liquids while allowing the passage of gases through the membrane into 
and out of the interior chamber thereby passively venting the container. 
In a second embodiment of the present invention, the 
gas-permeable/liquid-impermeable vent is integrally formed with the 
housing.

DETAILED DESCRIPTION OF THE INVENTION 
Referring now to the drawings, in FIG. 1 there is shown in a 
cross-sectional view a particularly preferred embodiment of a manually 
operated pump dispensing device, designated generally as 100, of the 
present invention. Referring to FIG. 1, the manually operated pump 
dispensing device 100 is provided with a housing 20 that is adapted to be 
sealingly attached to a liquid supply container 10. The housing 20 is used 
for mounting a dispensing pump 30 so that the dispensing pump 30 is in 
fluid communication with the container 10. 
The housing 20 can preferably be enclosed in a shroud 60. Typically the 
shroud 60 is used to encase the housing 20 and provide a more 
aesthetically pleasing package for the consumer. The housing 20 includes 
an outwardly extending discharge passageway 40 having a distal end 42 and 
a proximate end 44. The discharge passageway 40 is preferably formed 
integral to the housing 20. The discharge passageway 40 is in fluid 
communication with the dispensing pump 30. The housing 20 further includes 
an inlet passageway 46 that extends downwardly from the dispensing pump 
30. A nozzle portion 48 is attached in fluid communication to the distal 
end 42 of the discharge passageway 40. The nozzle portion 48 includes a 
discharge orifice 49. The nozzle portion 48 can preferably be molded from 
a thermoplastic material such as polypropylene, polyethylene, or the like. 
An actuator 50 preferably in the form of an actuation lever or trigger 52 
is pivotally attached to the housing 20 and connected to the dispensing 
pump 30. Inside the housing 20 the dispensing pump 30 is manually operated 
by actuation of the trigger 52 in a manner conventional to such dispensing 
pumps that are adapted to be actuated by a trigger 52. The dispensing pump 
30 preferably has a reciprocating piston 32 therein that slides in sealing 
relation to a pump chamber 34 when actuated and includes a spring member 
36 that biases the reciprocating piston 32 and trigger 52 to a 
non-dispensing position. A more detailed description of the features and 
components of such a conventional dispensing pump 30 can be found in, for 
example, U.S. Pat. No. 4,958,754 issued Sep. 25, 1990 to Stephen R. 
Dennis, which is hereby incorporated herein by reference. Conventional 
dispensing pumps of this general type are, for example, commercially 
available versions sold by Continental Sprayers, Inc. under the trade name 
"T8500". 
The container 10 must be suitable for storing liquid products. Preferably, 
the container 10 and the housing 20 are impervious to fluids. Such a 
container 10 comprises an interior chamber 12 and a hollow neck finish 14. 
The neck finish 14 is preferably located at the upper most portion of the 
container 10 and is used to sealingly attach the container 10 to the 
housing 20 and provides access to the interior chamber 12. The container 
10 can be constructed of various materials that are well known in the art, 
such as metals, glass, and the like. Preferably the container 10 is 
constructed of a plastic material, for example, polyethylene, polyvinyl 
chloride, polyethylene terephthalate, polyester, polypropylene, 
polycarbonate, nylon, or the like. Typically such a container 10 is formed 
by blow molding but such container 10 can be formed in various shapes and 
sizes by various methods well known in the art. 
On the housing 20, located opposite the discharge passageway 40, there is a 
closure 22. Preferably, the closure 22 has threads 24 therein and is made 
to mate with threads on the neck finish 14 of the container 10. In this 
manner the housing 20 is threaded onto the container 10 and the dispensing 
pump 30 is placed in fluid communication with the interior chamber 12 
through the inlet passageway 46. The inlet passageway 46 can be adapted to 
connect to a hollow dip tube 62 which places the inlet passageway 46 in 
fluid communication with the liquid product stored within the interior 
chamber 12 of the container 10. Alternatively, the closure 22 and neck 
finish 14 can be constructed in any manner known in the art so as to form 
a variety of sealingly attached connections between the container 10 and 
the manually operated pump dispensing device 100, for example, a snap-fit, 
bayonet-fit, plug-fit, quick disconnect, or the like. 
Also included on the housing 20 is a flange 28. The flange 28 extends 
radially outwardly around the inlet passageway 46. The closure 22 is 
connected to the housing 20 by the flange 28. Preferably a portion of the 
flange 28 acts as a seal between the closure 22 and the neck finish 14 of 
the container 10. The housing 20, including the flange 28 and closure 22, 
along with the shroud 60 can be fabricated as individual parts or 
alternatively they can be integrally molded by, for example, injection 
molding or other methods well known in the art. Additionally, these 
components can be formed from various materials such as a thermoplastic 
material, for example, polypropylene, polyethylene, polystyrene, 
polyester, polyvinyl chloride, polycarbonate, nylon, or the like. 
The housing 20 further includes a vent aperture 70 therethrough. The vent 
aperture 70 extends through the flange 28 thereby allowing communication 
between the interior chamber 12 and the exterior environment. In this 
preferred embodiment, as shown in FIG. 1, the housing 20 includes an 
outwardly opening bore 72 having an outer end 73 and an inner end 75 
formed within the housing 20 just below the dispensing pump 30. The 
outwardly opening bore 72 provides a conduit that leads to the vent 
aperture 70 positioned at the inner end 75 thereof The vent aperture 70 
extends through the housing 20 to permit ambient air from the environment 
to enter into the interior chamber 12 of the container 10 while also 
allowing gasses within the interior chamber 12 to escape and flow into the 
environment. Preferably a cylindrically shaped connecting ring 74 attached 
to the flange 28 forms the periphery of the vent aperture 70. The 
connecting ring 74 extends downwardly from the flange 28 to a position 
within the interior chamber 12 of the container 10 above the liquid 
product. 
Attached to the connecting ring 74 is a means for passively venting the 
manually operated pump dispensing device 100 and associated container 10 
to atmospheric pressure both during periods of use (i.e., during and 
immediately after a dispensing cycle) and non-use (i.e., static conditions 
without user interaction). In the present invention, the means for 
passively venting the manually operated pump dispensing device 100 
preferably comprises a gas-permeable/liquid-impermeable vent 80. This 
gas-permeable/liquid-impermeable vent 80 is preferably in the form of a 
venting module 82 which allows gasses generated within the interior 
chamber 12 to exit to atmosphere and avoid over pressurizing the container 
10 while also allowing ambient air to enter into the container 10 in order 
to avoid collapse of the container 10 when the liquid product is 
dispensed. Additionally, the liquid product stored within the container 10 
can not permeate the venting module 82 and thus spillage or leakage of the 
liquid product is avoided. This venting module 82 therefore provides 
two-way venting during periods of use as well as non-use and thereby 
passively vents the container 10. 
The venting module 82 comprises a membrane 84 and a support frame 86 having 
open spaces formed therein. The support frame 86, as seen in FIG. 2, 
preferably comprises a cylindrical, hollow cap 87 with support arms 88 
being spaced away from each other forming open spaces therebetween. The 
support arms 88 extend between the hollow cap 87 and a closed cylindrical 
collar 89. This support frame 86 is preferably injection molded of 
polypropylene, polyethylene terephthalate, polyethylene, nylon, or other 
polyolefins, or copolymers thereof Preferably the collar 89 has rounded 
edges in order to avoid damage to the membrane 84 during shipment and 
handling. Although this is a preferred configuration for the support frame 
86, various other configurations can also be utilized. 
As best shown in FIG. 3, the cap 87 is preferably sized to provide a 
frictional fit with the connecting ring 74 thus allowing the support frame 
86 to be attached to the housing 20. The connecting ring 74 can preferably 
comprise a first cylindrical wall 76 concentric to a second cylindrical 
wall 78 wherein the space between the first and second cylindrical walls 
76, 78 is sized to frictionally engage the cap 87 of the venting module 
82. A lip 85 which extends inward from the cap 87 to the support arms 88 
provides a surface on which a force can be applied in order to engage the 
frictional fit between the cap 87 and connecting ring 74 thereby attaching 
the venting module 82 to the flange 28 on the housing 20. Alternatively, 
the attachment feature between the cap 87 and connecting ring 74 can be 
formed of various mechanisms known in the art. For example, the attachment 
feature can be an outwardly protruding rim along the circumference of the 
connecting ring 74 with a corresponding circumferential groove or recess 
along the inside of the cap 87 forming a snap fit engagement when the cap 
87 is fitted over the connecting ring 74. Furthermore, the cap 87 can be 
affixed to the connecting ring 74 by use of permanent attachment methods, 
such as adhesive bonding or even integral molding, or by use of other 
temporary attachment methods, such as a threaded connection. 
The membrane 84 provided herein must be impermeable to liquid flow but 
permeable to gas flow. Gas permeable as used herein refers to the ability 
of the membrane 84 to allow gasses to pass through the membrane 84. 
Preferably, the venting module 82 will have an air flow rate of between 
about 400 cc and about 650 cc per minute when exposed to an air pressure 
of about 400 mm of water. As used herein, liquid impermeable refers to the 
ability of the membrane 84 to resist the passage of liquids therethrough. 
Preferably, the venting module 82 will not allow a single drop of water 
(visible to the naked eye) to pass through the membrane 84 when exposed to 
an increasing water pressure (increased to about 4500 mm of water at about 
100 mbar/min.) of up to about 4500 mm of water, and held at about 4500 mm 
of water for a period of five minutes. 
The thickness of the gas-permeable - liquid impermeable membrane 84 can be 
selected based on the thickness of the associated components it is affixed 
onto but typically such a membrane 84 is a thin layer, that is preferably 
having a thickness in the range of about 0.01 mm to about 2 mm, and most 
preferably from about 0.05 mm to about 0.5 mm. The membrane 84 can be 
composed of a synthetic material, for example, a microporous plastic film. 
The size of the pores through the membrane material are such as to allow 
passage of air and gasses therethrough while being impermeable to liquids. 
The membrane 84 can be selected from among various manufacturers having 
pores with a diameter preferably in the range of from about 0.005 .mu.m to 
about 10 .mu.m, and more preferably from about 0.01 .mu.m to about 3 
.mu.m, and most preferably from about 0.2 .mu.m to about 1 .mu.m. For 
example, these membranes 84 can preferably be manufactured from an acrylic 
copolymer using a solvent evaporation process in which the acrylic 
copolymer is processed to distribute a fine distribution of volatile 
components within the polymer. More preferably the membrane 84 is 
manufactured from an acrylic nitrile polymer. These volatiles are then 
evaporated during curing of the membrane producing the porous membrane 
structure. Thus, the actual membrane material can be very delicate and is 
typically not used without the support frame 86. 
In order to repel liquids, the membrane 84 is treated with a material to 
aid in repelling liquid penetration while minimizing the restriction to 
gas passage. Preferably, this treatment includes a hydrophobic coating 
being applied to the membrane 84. This hydrophobic coating preferably 
consists of a fluoro-monomer and more preferably a fluoroacrylate monomer. 
The membrane 84 is soaked in this fluoro-monomer during production and the 
entire membrane 84 is UV cured in order to polymerize the fluoro-monomer. 
This coating is throughout the membrane 84 and is not just on the surface. 
This preferred membrane 84 is made using a polyester material having a 
pore size of about 0.8 microns and is commercially available from Gelman 
Sciences Inc. being manufactured under the trade name Versapor.RTM. R 
Membrane V800TR. The dry air flow through this preferred membrane 84 is 
preferably from between about 5 liters/min./cm.sup.2 to about 15 
liters/min./cm.sup.2 at a pressure of about 13.5 psi, and more preferably 
about 10 liters/min./cm.sup.2 at a pressure of about 13.5 psi. Additional 
microporous membrane materials can include, for example, non-woven plastic 
films such as the non-woven spunbonded polyethylene film material sold 
under the trade name, Tyvek manufactured by the Du Pont Company. Various 
other synthetic membranes 84 prepared by sintering, stretching, 
track-etching, template leaching and phase inversion methods are also 
useful with the invention described herein. 
The venting module 82 of the most preferred embodiment has a length of 
between about 15 mm to about 17 mm and has a diameter of between about 8 
mm to about 9 mm. The cap 87 has an internal diameter of preferably about 
6.4 mm to about 6.5 mm and also preferably has a length of about 5 mm to 
about 6 mm. In this embodiment, the tapered section of the venting module 
82 contains membrane pieces 84 that are preferably about 8 mm long and are 
about 6 mm wide. In this most preferred embodiment, the venting module 82 
has two membrane pieces 84 spanning between and affixed to two support 
arms 88. Although this is a most preferred embodiment for the venting 
module 82, various other configurations and sizes can also be utilized. 
The membrane 84 is affixed onto the support frame 86 preferably in a manner 
such that the membrane 84 spans the open spaces in the support frame 86. 
More preferably, the membrane 84 is affixed in a manner that surrounds the 
support frame 86 or encases the support frame 86. FIG. 3 depicts a view of 
the membrane 84 affixed to the support frame 86. One method of affixing 
the membrane 84 onto the support frame 86 is to cast or heat seal the 
membrane 84 onto preferably a non-woven nylon or polyester fiber sheet 
type support frame 86. This provides an added degree of mechanical 
integrity. More preferably the venting module 82 can be manufactured using 
an insert molding process. The membrane material can be fed into a split 
mold and when the mold is closed around the membrane 84, the membrane 84 
is cut to the correct dimensions and then folded into the mold cavity. The 
membrane 84 is next clamped into the cavity and a resin is then injected 
into each cavity. The resin forms a leak tight seal with the membrane 
material and thus the support frame 86 is affixed to the membrane 84 
forming the venting module 82. 
In a first alternative embodiment, the membrane 84 can be formed integral 
to the flange 28 on the housing 20 of the manually operated pump 
dispensing device 100. FIG. 4 depicts a partial cross-sectional view of 
this first alternative embodiment showing the membrane 84 integrally 
attached over the vent aperture 70 of the housing 20. When the membrane 84 
is integrally formed with the housing 20 the support frame 86 and venting 
module 82 are eliminated since the membrane 84 is simply supported by the 
flange 28. The same processes previously mentioned can be utilized to 
create the membrane 84. The membrane 84 can be integrally affixed to the 
housing 20 over the vent aperture 70 in various leak tight manners well 
known in the art. For example, the membrane 84 can be molded, heat sealed, 
ultrasonically welded, or bonded to the housing 20 using an adhesive, 
glue, or the like. 
During operation, the container 10 is filled with a liquid product, such 
as, for example, carpet cleaners, hard-surface cleaners, household 
cleaners, dishwashing liquid, liquid detergents, liquid disinfectants, 
liquid bleaches, peroxide bleach, liquid car care products, liquid 
shampoos, personal/beauty care liquids, or the like. The manually operated 
pump dispensing device 100 is attached to the container 10 by a closure 22 
with dip tube 62 extending below the liquid product surface. When 
dispensing or spraying is desired, the trigger 52 is manually moved by the 
user upon the application of an operating force, thereby causing the 
dispensing pump 30 to actuate. Actuation of the dispensing pump 30 causes 
the liquid to flow under pressure through the discharge passageway 40 and 
into the nozzle portion 48 and then out of the discharge orifice 49. When 
the trigger 52 is released, the trigger 52 and dispensing pump 30 returns 
to the non-dispensing position under the urging of a biasing spring force. 
As the dispensing pump 30 returns to its original non-dispensing position, 
a negative pressure, or vacuum is created within the pump chamber 34. 
Ambient air is allowed to enter the container 10 through the venting 
module 82 and vent aperture 70. The venting module 82 prevents the liquid 
product from passing through the vent aperture 70 even when the container 
10 is agitated or inverted during a dispensing cycle. Simultaneously, 
liquid product is drawn up into the pump chamber 34 of the dispensing pump 
30 through the dip tube 62 thereby preparing the dispensing pump 30 for 
the next dispensing cycle. Subsequent actuation and release of the trigger 
52 repeats the above dispensing cycle and allows the liquid product to be 
dispensed or sprayed through the discharge orifice 49. 
If the liquid is to be dispensed in the form of a spray, the nozzle portion 
48 can be of the pressure swirl or impingement variety, or the like. When 
a pressure swirl nozzle is utilized, the liquid exiting the discharge 
orifice 49 is in the form of a thin conical sheet which quickly breaks up 
into fluid particles. When an impingement nozzle is used the liquid is 
discharged in impinging streams that break up upon impact or interaction 
with each other. Alternatively, the liquid can be dispensed in the form of 
a foam, stream, spray or any combination of these forms. Thus, the nozzle 
portion 48 can comprise various types of nozzles that are well known in 
the art for dispensing liquids through a discharge orifice 49. 
After operation and during periods of non-use, air as well as other gasses 
can flow through the venting module 82 into and out of the container 10 
through the gas-permeable/liquid-impermeable membrane 84. This allows for 
off-gassing during periods of non-use. Off-gassing typically occurs when 
gasses are naturally generated by the liquid product housed within the 
container 10. These gasses are vented to the environment through the 
venting module 82 as the pressure within the container 10 increases 
thereby avoiding over stressing or over pressurizing the container 10. 
Since the venting module 82 allows gasses to pass through without any 
interaction from the user, this manually operated pump dispensing device 
100 acts to passively vent the container 10. Additionally, since the 
venting module 82 is liquid impermeable, no liquids are allowed to escape 
to the environment through the venting module 82. 
Various modifications to the above described manually operated pump 
dispensing device 100 can be made without departing from the spirit and 
scope of the claims. For example, as shown in FIG. 5, a second alternative 
embodiment of the manually operated pump dispensing device 200 includes a 
housing 220 sealingly attached to a container 210 and a flexible pump 230 
mounted within the housing 220. In this embodiment, the dispensing pump 30 
of FIG. I is replaced by the flexible pump 230. The flexible pump 230 
comprises a resilient structure 232 which permits the flexible pump 230 to 
be compressed by the trigger 252 wherein the flexible pump 230 returns to 
its initial non-dispensing position when the trigger 252 is released. The 
resilient structure 232 can be molded from a resilient thermoplastic such 
as polypropylene, polyethylene or the like, or from an elastomeric 
material such as a thermoplastic elastomer, rubber, or the like. This 
embodiment also includes a discharge passageway 240 having a nozzle 
portion 248 with a discharge orifice 249 and also includes an inlet 
passageway 246 extending into the interior chamber 212 of he container 
210. The discharge passageway 240 and the inlet passageway 246 are both in 
fluid communication with the flexible pump 230. Preferably, the trigger 
252 is pivotally attached to the housing 220 and also connected to the 
flexible pump 230. A more detailed description of the features and 
components of such a flexible pump 230 can be found in, for example, U.S. 
Pat. No. 5,303,867 issued Apr. 19, 1994 to Robert J. Peterson, which is 
hereby incorporated module 282 including a 
gas-permeable/liquid-impermeable membrane 284 is attached over a vent 
aperture 270, located in an alternative position, in the housing 220. The 
vent aperture 270 extends through the housing 220, thereby allowing 
communication between the interior chamber 212 and the environment. Thus, 
the venting module 282 permits ambient air from the environment to enter 
into the interior chamber 212 of the container 210 while also allowing 
gasses within the interior chamber 212 to escape and flow to the 
environment, thereby passively venting the container 210. 
Although particular versions and embodiments of the present invention have 
been shown and described, various modifications can be made to this 
manually operated pump dispensing device 100 without departing from the 
teachings of the present invention. The terms used in describing the 
invention are used in their descriptive sense and not as terms of 
limitation, it being intended that all equivalents thereof, be included 
within the scope of the appended claims.