BACKGROUND OF THE INVENTION
I. Field of the Invention
[0001] The present invention relates generally to fluid dispensing mechanisms and, more
particularly, to an improved dispenser of simplified construction which does not require
seals, particularly sliding seals, or springs for its operation, yet applies precisely
controlled quantities of the fluid to a receiving surface.
II. Description of the Prior Art
[0002] There are a number of known designs for dispensing fluids such as adhesives, sealants,
and the like, at accurately controlled flow rates, in accurate quantities, and for
accurate placement on a receiving surface.
[0003] In one instance, a spring biased piston is pneumatically operated to open and close
a valve, as needed to control the flow of fluid to be dispensed from an outlet nozzle.
The piston is provided with seals to prevent flow of the fluid in directions other
than through the valve and these seals are subject to deterioration and wear, particularly
when the fluid being dispensed is heated.
[0004] In another known dispenser design, a diaphragm is pneumatically operable to allow
or interrupt flow of the fluid to a dispensing nozzle. The diaphragm can be moved
by an actuating rod between a bowed position enabling flow to occur between inlet
and outlet conduits and a planar position interrupting such flow. Again, proper sealing
of the valve is a continuing problem. Specifically, it has not been possible heretofore
to adequately seal the unit to prevent flow of the fluid into the actuating mechanism
regardless of the type or number of seals being employed by the mechanism.
[0005] Another type of dispenser utilizes a positive displacement type of valve in which
a quantity of the fluid is admitted into a chamber whereupon a piston then forces
that quantity out through the dispensing outlet or nozzle. Again, in this instance,
seals are necessary components of the mechanism and are not totally effective in satisfying
their intended purpose.
[0006] In each of the foregoing instances, loss of the fluid that does not issue from the
outlet nozzle but finds its way instead into other cavities of the dispensing mechanism
is not the primary concern. Rather, when the fluid is a sealant, or adhesive material,
it subsequently accumulates, then hardens, and thereby has a detrimental effect on
the operation of the dispensing mechanism, even to the point of rendering it inoperative.
[0007] Yet another known design of fluid dispenser utilizes a pinch valve according to which
an actuator is selectively moved into or out of engagement with flexible tubing which
extends from a source of supply to the dispensing head. While seals are not a particular
problem with this design of dispenser, the length of the tubing necessary for this
design is sufficiently long that it undesirably results in a delayed response time
between the operation of the valve and the resultant flow of fluid being dispensed
from the nozzle. This, in turn, causes inconsistent flow through the nozzle thereby
reducing accuracy, namely, placement of a particular quantity of fluid at a particular
location at a particular time.
SUMMARY OF THE INVENTION
[0008] It was the knowledge of the prior art, generally as noted above, and the problems
existing which gave rise to the present invention. The present invention relates to
a simplified fluid dispenser for dispensing precise quantities of fluid without requiring
special seals or springs. It comprises a housing defining a fluid reservoir having
an inlet for delivery of pressurized fluid to the reservoir, and including a valve
seat defining an outlet for dispensing fluid from the reservoir. A deformable closure
member overlies an open end of the housing opposite the outlet and normally biases
a valve engageable with the valve seat to the closed position. When selectively deformed,
the closure member is effective to move the valve to the open position to dispense
a quantity of the fluid from the reservoir. When released, the closure member returns
to its normal condition, returning the the valve to the closed position.
[0009] The present invention exhibits a large number of features and benefits not generally
found in the prior art. For example, it can dispense fluids having an extremely broad
range of viscosities, namely, from one centipoise to a value substantially in excess
of one million centipoises.
[0010] Furthermore, the dispenser of the invention can be turned on and off instantaneously,
that is, starting and stopping a flow of fluid occurs at substantially the same time
as operation of the valve actuator. Additionally, fluid does not drip from the outlet
nozzle when the valve of the novel dispenser is closed but rather, because of its
unique design, the fluid is drawn back thereby avoiding drippage of the fluid.
[0011] The dispenser of the invention can utilize low cost materials, such as plastic. Since
it utilizes a small number of parts and requires no special seals or springs, and
because the parts are interchangeable, both for different materials and for different
sizes, it is significantly less costly to manufacture than its prior art counterparts.
[0012] Another significant feature of the invention resides in its construction and manner
of operation according to which movement of an actuator used to operate the dispenser
causes simultaneous and equal movement of the valve off its seat for dispensing the
fluid. This feature allows the dispenser to operate at very high actuation speeds.
Indeed, the dispensing of the fluid is substantially simultaneous with the actuation
of the valve.
[0013] The invention utilizes no internal seals, especially sliding seals which are particularly
susceptible to wear. Also, it uses a minimum of parts, and flow of the fluid within
the dispenser can only occur in the direction of the outlet. As a result, the operation
of the invention is not hindered by seals which are particularly susceptible to becoming
inoperative by being caked or gummed up with dried or partially dried sealant or adhesive
material which are commonly dispensed products.
[0014] Other and further features, objects, advantages, and benefits of the invention will
become apparent from the following description taken in conjunction with the following
drawings. It is to be understood that both the foregoing general description and the
following detailed description are explemary and explanatory but are not restrictive
of the invention. The accompanying drawings, which are incorporated in and constitute
a part of this invention, illustrate some of the embodiments of the invention and,
together with the description, serve to explain the principles of the invention in
general terms. Like numerals refer to like parts throughout.
BRIEF DESCRIPTION OF THE DRAWINGS
[0015]
Fig. 1 is a side elevation view of a fluid dispensing mechanism according to the invention
and including a diagrammatic representation of an operating and control mechanism
associated therewith;
Fig. 2 is a partial cross section view of the dispensing mechanism illustrated in
Fig. 1 illustrating the mechanism in its relaxed condition;
Fig. 3 is a detail view of a component of the fluid dispensing mechanism;
Fig. 4 is a detail cross section view illustrating a portion of a modified fluid dispensing
mechanism;
Fig. 5 is a cross section view, similar to Fig. 2, illustrating the fluid dispensing
mechanism in its operative condition;
Figs. 6 and 7 are detail perspective views illustrating other embodiments of the invention;
Figs. 8 and 9 are detail cross section views illustrating still other embodiments
of the invention; and
Fig. 10 is a side elevation view, partially cut away and in section, illustrating
still another embodiment of the invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0016] Turn now to the drawings and, initially, to Fig. 1 which depicts a fluid dispenser
20 which embodies the invention. Throughout the disclosure, the term "fluid" will
be taken to mean any substance which has the property of flow but excluding gases
and total solids while not excluding those substances having solids suspended in a
liquid. Indeed, those substances which the dispenser 20 is intended to dispense cover
an extremely broad range of viscosities, for example, from water which has a viscosity
of one centipoise to tar-like substances which have a viscosity of one million centipoises,
or greater.
[0017] Viewing now Fig. 2, the dispenser 20 comprises a housing 22 which may be cylindrical,
as illustrated, or of some other suitable shape, so as to define a reservoir 24 therein
capable of containing a pressurized fluid. The housing 22 has an inlet 26 which may
be trapped to threadedly receive a suitable fitting 28 attached to one end of a supply
conduit 30, the other end of which connects to a source 32 of the fluid which includes
a suitable pump mechanism for providing the fluid to the reservoir 24 on an as-needed
basis. One end of the housing 22 may be provided with a counterbore 34, the outermost
end of which may be taped to threadedly receive a nozzle 36. The nozzle 36 serves
to carefully direct the flow of the fluid dispensed from the reservoir 24 in a manner
to be described.
[0018] At locations intermediate the reservoir 24 and the counterbore 34, the housing 22
is provided with a restricted region 40 in which is formed an outlet 42 defined by
a valve seat 44 located immediately downstream thereof. The end of the housing 22
opposite the counterbore 34 may be similarly counterbored to form a continuous annular
end surface 46 which thereby defines an annular flange 48 extending longitudinally
away from the surface 46.
[0019] As seen particularly well in Fig. 2, a closure member in the form of hemispherical
resilient dome 50 overlies the end of the housing 22 defined by the end surface 46.
The dome 50 is composed of any suitable deformable material having a memory such that
it can be deformed by an outside force, then return to its original configuration
when that force has been withdrawn. DELRIN brand plastic is one example of such a
suitable material, particularly for low viscosity fluids, but other plastics, metals,
or composite materials with similar memory characteristics can be utilized. The dome
50 has a central opening 52 and terminates at a continuous rim 54 which is engageable
with the end surface 46.
[0020] The dome 50 is one component of an actuator mechanism which also includes an elongated
stem 56 and a suitable fastener 58. The stem 56 extends through the opening 52 at
which it is fittingly attached to the dome 50 and extends through the reservoir 24
and through the outlet 42. At its end farthest from the dome 50, the stem 56 is provided
with a gate 60 which is engageable with the valve seat 44 to thereby define a valve
for the dispenser 20. The gate 60 may be integrally formed with the stem 56, or it
may be a separate item and suitably bonded or fastened to the stem. It will be appreciated
that to assure the optimum operation of the dispenser 20, the valve seat 44 must be
precisely formed and have a high degree of smoothness to assure complete closure of
the outlet 42 when the gate 60 engages the valve seat 44. The valve seat should be
composed of an inert material, examples being ceramics, stainless steel, or a hard
plastic. As seen in Fig. 3, the gate may be desirably spherical in the manner of a
bead 60A formed with a diametral bore 61 therethrough. Such beads 60A may be composed
of plastic, glass, ceramic, metal or any other suitable material capable of being
formed to have a high degree of roundness so as to properly and completely engage
the valve seat 44.
[0021] The dome 50 may be provided with a hollow chimney 62 extending longitudinally outwardly
from an outer surface 64 to an extreme end surface 66. An end of the stem 56 opposite
the gate 60 projects outwardly from the dome 50 and may be threaded as at 68 to threadedly
receive the fastener 58 which may be in the form of a nut.
[0022] The nut 58 is turned on the stem 56 until it engages the end surface 66. In the alternative,
a suitable seal member 70 may be received on the stem 56 intermediate the surface
66 and the nut 58 to further prevent escape of any fluid from the reservoir 24. In
either event, the nut 58 is tightened down to a sufficient extent that the gate 60
is caused to firmly engage the valve seat 44 and such that, simultaneously, the rim
54 engages the end surface 46. At the same time, the nut 58 should not be tightened
to such an extent as to cause any deformation of the dome 50. When this relationship
has been achieved such that any movement of the dome is immediately imparted to the
gate 60, without lost motion, it may be desirable to suitably bond the stem 56 to
the dome 50 and the nut 58 and the seal 70 together and both, in turn, to the dome
50. With the nut 58 tightened down as indicated in Fig. 2, it will be noted that the
outer diameter of the dome 50 adjacent its rim 54 is substantially the same as the
inner diameter of the annular flange 48. Although the annular flange 48 may not be
necessary for the purposes of the invention, it does serve as an aid to prevent the
lateral expansion of the dome adjacent its rim 54 during the operation of the invention
as will be described. In another embodiment of the invention as seen in Fig. 4, it
may be desirable to replace the annular flange 48 with an annular groove 72 to engageably
receive the rim 54 of the dome 50.
[0023] In the operation of the invention, an operator can grasp the housing 22 in his hand,
for example, like holding a pencil, while an extreme end 74 of the stem 56 is manually
or automatically activated. Thus, when the stem 56 is depressed in the direction of
an arrow 75 as indicated in Fig. 5, the dome 50 is deformed and this deformation allows
the gate 60 to leave its engagement with the valve seat 44. The pressure within the
reservoir 24 caused by the source 32 is effective to cause the fluid therein to pass
through the outlet 42 and eventually through the nozzle 36 and onto an appropriate
receiving surface. When the force of the actuating mechanism is released from the
extreme end 74, the dome 50 returns to its original position and draws with it the
gate 60 which again engages the valve seat 44. The magnitude of the gate 60 and its
closing velocity cause the fluid being dispensed to rapidly reverse direction resulting
in an immediate termination of flow and elimination of drippage of the type often
associated with known devices. The viscosity of the fluid is also an important factor
in combination with the magnitude and velocity of the gate in achieving this desired
goal. Specifically, the greater the magnitude of the gate, the greater its velocity
and the higher the viscosity of the fluid, the greater is the effect of terminating
flow and eliminating drippage. In this manner, there is no dripping associated with
the dispenser 20 as flow is caused to terminate. This is true regardless of the viscosity
of the fluid and it was previously explained that the dispenser 20 is useful for dispensing
fluids having an extremely wide range of viscosities, namely, within the range of
one to one million plus centipoises.
[0024] The dispenser 20 is capable of dispensing part or all of the fluid contained in the
reservoir 24. It will be appreciated that the pump mechanism at the source 32 constantly
keeps the reservoir 24 pressurized, even when flow of additional fluid may have been
terminated. Thus, if desired, all of the contents of the dispenser 20 may be fully
dispensed, leaving substantially no undesired residue of the fluid in the reservoir
24. It is also possible to evacuate all fluid from the dispenser 20 back to the source
32, should that be desired.
[0025] As indicated in Fig. 1, not only is the dispenser 20 manually usable, but the stem
56 can be driven by a variety of different mechanisms which can even be computer controlled.
Thus, a drive mechanism 76 may be, for example, an electrically operated solenoid,
or a mechanical cam, or a hydraulically or pneumatically operated device. Operation
of the drive mechanism may be under the control of an appropriate computer 77 and,
using any of these types of drive mechanisms, the dispenser 20 can be readily adapted
for robotics usage. The computer 77 may also control the source 32 for regulating
the amount and pressure of the fluid provided to the reservoir 24. It is especially
attractive in this type of a use because its simplicity of construction and operation
assures that it can operate for exceptionally long periods of time between failures,
primarily as a result of the lack of moving parts such as sliding seals.
[0026] While components of the dispenser 20 other than the dome 50 could be made of durable,
long lasting, but expensive, materials such as stainless steel, it may desirable and
practical to use less expensive plastic or composite materials in its construction.
Such plastic or composite materials could be easily and inexpensively molded. Additionally,
in another embodiment of the invention, the nut 58 may be replaced by some other type
of fastener. In one instance, for example, as seen in Fig. 6, a cotter pin 78 may
be utilized in a known fashion in combination with a backing washer 80 so positioned
on the stem 56 to assure that the gate 60 is engaged with the valve seat 44 when the
dome 50 is in its relaxed condition. Alternatively, as seen in Fig. 7, a speed nut
82 may be received on the end of the stem 56 to maintain that relative positioning
of the gate 60 and valve seat 44. Both of the latter two constructions are desirable
because there is no need to tap the end of the stem 56, with a resulting savings in
cost. Indeed, it would be possible for the dispenser to be constructed in some other
fashion such that an end of the stem 56 opposite the gate 60 is permanently fixed
to the dome 50 in a manner not requiring a fastener.
[0027] As seen in Fig. 8, a modified closure member, specifically, cap member 84, is illustrated
in place of the dome 50, and is seen to be of concave cross section. While the cap
member 84 is not hemispherical as the dome 50 and is therefore much shallower, that
is, occupies much less distance in a direction along the stem 56 between the nut 58
and its peripheral rim 86, it has all of the other characteristics of deformability
and plastic memory that the dome 50 has.
[0028] Yet another embodiment is illustrated in Fig. 9. In this instance, another modified
closure member in the form of a bellows 94 replaces the dome 50. Again, the bellows
possesses the characteristics of deformability and plastic memory which are necessary
for the successful operation of the dispenser of the invention. It is particularly
desirable for use in those situations in which a highly viscous fluid is being dispensed
by reason of its ability to operate through a relatively greater range of movement.
This enables the gate 60 to be moved a greater distance away from the valve seat 44
to more readily permit flow of fluid to the nozzle 36.
[0029] Yet another embodiment of the invention is illustrated in Fig. 10. In this instance,
a modified housing 22A has an elongated inlet 88 disposed generally parallel to an
axis of the stem 56. A reservoir/adapter 90 integral with the housing 22A overlies
the inlet 88 and is connected as by a conduit 92 to a source 32A for the fluid. This
design may be utilized to receive highly viscous fluids which cannot easily be conducted
through smaller conduits and apertures. In all other respects, however, a dispenser
so modified would operate similarly to the dispenser 20. As noted above, it may be
preferable to use the bellow 87 in this situation in place of the dome 50.
[0030] It will also be appreciated that by using modern plastic molding techniques, the
housing 22 and dome 50, or equivalent closure construction may be an integral structure.
For this purpose, provision should be made for the wall thickness in the structure
opposite the gate 60 to be somewhat reduced from the remainder of the structure so
as to enable the flexing or deformation of the nature permitted by the dome 50, cap
member 84, or bellows 87. In this construction of the dispenser, the end of the stem
opposite the gate would be fixed to the deformable portion in some suitable fashion,
which may be in a manner as disclosed herein, or otherwise.
[0031] While preferred embodiments of the invention have been disclosed in detail, it should
be understood by those skilled in the art that various other modifications may be
made to the illustrated embodiments without departing from the scope of the invention
as described in the specification and defined in the appended claims.
1. Apparatus for dispensing precise quantities of a broad range of fluid products,
including adhesives, comprising:
a housing defining a reservoir for containing pressurized fluid;
valve means on said housing movable between an open position for dispensing the fluid
from the reservoir regardless of the orientation of said housing and a closed position;
and
deformable fluid tight closure means on said housing and connected to said valve means
normally biased to a relaxed condition for holding said valve means closed, said closure
means being operable, when deformed, to move said valve means to the open position.
2. Apparatus as set forth in Claim 1
wherein said closure means includes a substantially hemispherical dome having a generally
concave surface facing said valve means.
3. Apparatus as set forth in Claim 1
wherein said closure means includes a bellows facing said valve means.
4. Apparatus as set forth in Claim 1 including:
an elongated stem attached at one end to said closure means; and
wherein said housing has an outlet through which the fluid is dispensed; and
wherein said valve means includes a valve seat on said housing surrounding the outlet
from the reservoir and a gate at an end of said stem distant from said closure means,
said gate being engaged with said valve seat when said closure means assumes the relaxed
condition, said gate being spaced from said valve seat when said closure means is
deformed.
5. Apparatus as set forth in Claim 4
wherein said housing has an inlet to the reservoir; and
including:
a pressurized source of the fluid distant from said housing; and
conduit means connecting said source to the inlet to the reservoir for continually
replenishing the supply of fluid to the reservoir.
6. Appartus as set forth in Claim 5
wherein the inlet is elongated generally along the length of said housing; and
including:
reservoir/adapter means mounted on said housing so as to overlie the inlet;
said conduit means connecting said source to said reservoir/adapter means.
7. Apparatus as set forth in Claim 4 including:
drive means for selectively deforming said closure means to dispense the fluid through
the outlet.
8. Apparatus as set forth in Claim 4
wherein said closure means is a deformable member having a centrally disposed hole
therein; and wherein an end of said stem distant from said valve seat is fittingly
received through the hole in said deformable member; and
including:
fastener means on said stem engageable with said deformable member outside of the
reservoir to thereby draw said gate into engagement with said valve seat when said
deformable member assumes the relaxed condition.
9. Apparatus for dispensing precise quantities of a broad range of fluid products
including adhesives and sealants comprising:
a housing defining a fluid reservoir and having an inlet for delivery of pressurized
fluid to the reservoir and including a valve seat defining an outlet for dispensing
the fluid from the reservoir regardless of the orientation of said housing, said housing
being open at an end opposite said valve seat;
a deformable resilient fluid tight closure member overlying the open end of said housing;
and
an elongated stem including a gate member at one end and attached to said closure
member at its opposite end;
said closure member being responsive to an external force generally in the direction
of said valve seat to deform sufficient to disengage said gate member from said valve
seat and allow the fluid to be dispensed from the reservoir through the outlet;
said closure member being further responsive to removal of the external force as to
be restored to its original shape and to return said gate member into engagement with
said valve seat to terminate flow of the fluid through the outlet; and
nozzle means mounted to said housing adjacent the outlet for accurately directing
the flow of the fluid therefrom.
10. Apparatus for dispensing precise quantities of a broad range of fluid products,
including adhesives, comprising:
a housing defining a fluid reservoir and having an inlet for delivery of pressurized
fluid to the reservoir and including a valve seat defining an outlet for dispensing
the fluid from the reservoir regardless of the orientation of said housing;
a deformable member of said housing opposite said valve seat being movable between
a first position and a second position, said deformable member being in communication
with the reservoir and providing a fluid tight closure therefor; and
an elongated stem including a gate member at one end, said stem extending through
the outlet and fixed at an opposite end to said deformable member, and said gate member
being firmly engaged with said valve seat when said deformable member is in said
first position;
said deformable member being responsive to an external force generally in the direction
of said valve seat to move to said second position being thereby sufficiently deformed
to disengage said gate member from said valve seat and allow the fluid to be dispensed
from the reservoir through the outlet;
said deformable member being further responsive to removal of the external force as
to be restored to its first position to thereby return said gate member into engagement
with said valve seat to terminate flow of the fluid through the outlet.