NZ608686B2 - Applicator - Google Patents
Applicator Download PDFInfo
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- NZ608686B2 NZ608686B2 NZ608686A NZ60868613A NZ608686B2 NZ 608686 B2 NZ608686 B2 NZ 608686B2 NZ 608686 A NZ608686 A NZ 608686A NZ 60868613 A NZ60868613 A NZ 60868613A NZ 608686 B2 NZ608686 B2 NZ 608686B2
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Abstract
applicator such as a drenching gun for treating livestock is disclosed. The applicator comprises a fluid supply inlet (14), an outlet (4) and a barrel (1) having a barrel outlet (2) and a barrel inlet (15) in fluid communication, or selective fluid communication with the fluid supply inlet (14). A one way outlet valve (3) is in fluid communication with the barrel outlet (2) and with the outlet (4). A piston (5) is disposed in the barrel (1) with piston actuation means for moving the piston relative to the barrel. The applicator further comprises pressure limiting means for limiting a maximum pressure of fluid entering the barrel (1) from the fluid supply inlet (14). The pressure limiting means limits the pressure in the barrel so the outlet valve (3) is not activated unintentionally i.e. by a pressure surge. A one way outlet valve (3) is in fluid communication with the barrel outlet (2) and with the outlet (4). A piston (5) is disposed in the barrel (1) with piston actuation means for moving the piston relative to the barrel. The applicator further comprises pressure limiting means for limiting a maximum pressure of fluid entering the barrel (1) from the fluid supply inlet (14). The pressure limiting means limits the pressure in the barrel so the outlet valve (3) is not activated unintentionally i.e. by a pressure surge.
Description
APPLICATOR
The present invention relates to fluid applicators, and in particular, but not exclusively, to
applicators for use in applying animal remedies.
ound to the Invention
Animal remedies for sheep, cattle and the like are applied by a number of methods including
topical or “pour-on" application, oral application, injection and nasal infusion. Each of these is
typically dispensed from a "pistol grip" style dispensing means.
Typically such ators have a piston or plunger which can be reciprocated within a barrel by
squeezing and releasing a first handle relative to a second handle. The liquid to be dispensed
is drawn into the barrel through an inlet via a one way inlet valve when the plunger is withdrawn
inside the barrel, and is dispensed through a nozzle via an outlet valve when the plunger is
extended towards the outlet valve. Such an applicator is described in the ant’s New
Zealand patent No. 521084. the contents of which are herein incorporated by reference.
As is described above, conventional fluid applicators incorporate two one~way valves. These
valves are referred to as the inlet valve and the outlet valve.
The valves are typically biased with springs, so that they open only when there is a predefined
difference in the fluid pressure between the upstream side of the valve and the downstream
side. Fluid cannot flow rds through either valve, as flow in this direction will tend to push
the valves more tightly .
When the applicator is at rest, both valves are closed. When the applicator is in use, it is
intended that only one valve opens at a time. During the discharge stroke. the outlet valve is
pushed open by the raised fluid pressure within the barrel. During the refill , the inlet valve
is pushed open by fluid entering the barrel (where there is now a partial vacuum).
A problem with conventional applicators is that they require a relatively large force to e
the handles together during the application stroke of the . This may be fatiguing for the
operator, particularly when the ator is used to treat a large group of animals.
The large force is required e the outlet valve of a conventional applicator is set to open
only when there is a relatively large pressure in the barrel of the applicator. The reasons for this
are as s:
Firstly, the momentum of fluid travelling through the feed tube causes a pressure pulse
(sometimes referred to as water hammer) at the completion of the refill stroke. The magnitude of
this pressure pulse depends on factors such as the fluid velocity and the hardness of the feed
tube. This pressure pulse can potentially force open both the inlet valve and the outlet valve
simultaneously, and result in an unwanted discharge of fluid from the applicator. End-users
strongly dislike this discharge of fluid, even if it is only a small volume.
Secondly, if the fluid supply container is held higher than the applicator (for example in a
backpack) then the increased pressure can cause the fluid to flow continuously through the
applicator, even when it is not squeezed, or it may drip continuously.
It would be useful to p an applicator which allows for an outlet valve which opens under a
lower pressure than the ators of the prior art, but which does not allow any unwanted
discharge of fluid from the applicator outlet.
When the applicator is used in the veterinary and/or animal husbandry fields it should preferably
have the following characteristics:
. be simple and reliable, suited to use in an agricultural nment.
0 be inexpensive to implement.
0 not interfere with the dose accuracy of the applicator.
0 work regardless of the height of the fluid source relative to the applicator.
0 work regardless of the viscosity of the fluid.
0 work regardless of the speed of discharge or refill.
. work tly during all stages of the applicator’s ing cycle, including discharge,
refill, and unexpected pauses in mid—stroke.
o withstand attack by sive als.
Throughout the description and the claims, all reference to pressures are to gauge pressures,
Le. pressure relative to the ambient pressure. Therefore, a reference to zero pressure means
t pressure. Reference to negative pressure means suction. Reference to a partial
vacuum is any pressure below ambient pressure but greater than a total vacuum.
Reference to the “upstream" ion is towards the direction in the fluid flow path from which
fluid enters the applicator. Reference to the “downstream“ direction is to the direction in which
the fluid normally flows.
The reference to any prior art in the specification is not, and should not be taken as, an
acknowiedgement or any form of suggestion that the prior art forms part of the common general
knowledge in any y.
Object of the invention
it is an object of a preferred embodiment of the invention to provide an applicator which will
overcome or ameliorate at least one problem with such applicators at present, or at least one
which will provide a useful .
Other objects of the present invention may become nt from the following description,
which is given by way of example only.
Brief Summary of the Invention
According to one aspect of the present invention there is provided an applicator comprising:
a fluid supply inlet;
an outlet;
a barrel having a barrel outlet and a barrel inlet which is in fluid communication, or
selective fluid communication, with the fluid supply inlet;
a one way outlet valve in fluid communication with the barrel outlet and with the
outlet;
a piston moveable relative to the barrel and in seating ment with the barrel;
piston actuation means for moving the piston relative to the barrel;
the applicator further sing pressure limiting means for limiting a maximum
pressure of fluid entering the barrel from the fluid supply inlet.
Preferably, the pressure limiting means is configured such that the fluid entering the
barrel has a pressure which is at or below an ambient heric pressure.
ably, the pressure limiting means is configured such that the fluid entering the
barrel has a pressure which is at or beiow a pressure required to open the outlet valve.
Preferably, the pressure limiting means is provided at or adjacent the barrel inlet.
Preferably, the pressure limiting means is integral with the .
Preferably, the pressure limiting means comprises a diaphragm.
Preferably the diaphragm is annular in shape.
Preferably a first side of the diaphragm is in fluid communication, or selective fluid
communication, with fluid in the barrel.
Preferably an opposite second side of the agm is exposed to ambient atmospheric
pressure.
Preferably displacement of the diaphragm changes an internal volume of a conduit
supplying fluid to the barre! inlet.
Preferably the agm is carried by the piston.
Preferably the applicator is provided with a one way valve means for preventing fluid
flow from the barrel though the barrel inlet.
Preferably the pressure limiting means is d to prevent fluid flow from the barrel
inlet to the fluid suppiy inlet.
Preferably the pressure limiting means comprises a first valve head and a first valve
seat, wherein the first valve head can be moved from a closed on to an open
position by movement of the diaphragm.
Preferably the pressure limiting means comprises a second valve head and second
valve seat. wherein the second valve head is connected to the first valve head and
moves with the first valve head.
Preferably a pressure difference across said first valve head is substantially equal to a
pressure difference across said second valve head.
Preferably the pressure difference across said first valve head creates a resultant force
in a first direction and the pressure difference across said second valve head creates a
resultant force in a second direction which is opposite to the first direction.
ably the ant forces are substantially equal.
Preferably the resultant force on the second valve head is greater than the resultant
force on the first valve head.
ing to a second aspect of the present invention there is provided an applicator
comprising:
a fluid supply inlet;
an outlet;
a barrel having a barrel outlet and a barrel inlet in fluid communication, or selective
fluid communication, with the fluid supply inlet;
a one way outlet valve in fluid communication with the barrel outlet and with the
outlet;
a piston moveable reiative to the barrel and in sealing engagement with the barrel;
piston actuation means for moving the piston relative to the barrel; and
a diaphragm in fluid contact, or ive fluid communication, with a fluid within the
barrel, wherein movement of the diaphragm controls a valve means provided between
the fluid supply inlet and the barrel inlet.
According to a third aspect of the present invention there is provided an applicator
system sing an ator and fluid supply conduit, the applicator comprising:
a fluid supply inlet;
an outlet
a barrel having a barrel outlet and a barrel inlet in fluid communication, or selective fluid
communication, with the fluid supply inlet;
a one way outlet valve in fluid communication with the barrel outlet;
a piston moveable relative to the barrel and in sealing engagement with the barrel;
piston actuation means for moving the piston relative to the barrel;
the fluid supply conduit having an inlet and an outlet which is in fluid communication, or
selective fluid communication, with the fluid supply inlet of the applicator;
the system further comprising pressure limiting means for limiting a maximum pressure
of fluid entering the barrel in use.
According to a further aspect of the present invention there is provided an ator
substantially as herein described with reference to any one of Figures 1 to 3, Figures 4 and 5, or
Figures 6 to 8.
The invention may also be said broadly to consist in the parts, elements and features referred to
or indicated in the specification of the application, individually or collectively, in any or all
combinations of two or more of said parts, ts or features, and where specific integers are
mentioned herein which have known equivalents in the art to which the invention s, such
known equivalents are deemed to be incorporated herein as if individually set forth.
r s of the ion, which should be considered in all its novel aspects, will
become apparent from the following description given by way of example of possible
embodiments of the invention.
Brief Description of the s
Figure 1 is a diagrammatic cross-section side view of an applicator according to one
ment of the present invention.
Figure 2 Is an enlarged diagrammatic cross~section side view of the piston head and
pressure limiting means of the applicator shown in Figure ’l with the pressure
limiting valve closed.
Figure 3 Is an eniarged diagrammatic section side view of the piston head and
pressure limiting means of the applicator shown in Figure ’l with the pressure
limiting valve open.
Figure 4 Is a diagrammatic cross-section side View of an appiicator according to a second
embodiment of the present invention.
Figure 5 Is an enlarged diagrammatic cross~section side View of the piston head and
re limiting means of the applicator shown in Figure 4 with the pressure
’10 limiting valve closed.
Figure 6 is a diagrammatic cross-section side view of an applicator according to a third
embodiment of the present invention.
Figure 7 is an enlarged diagrammatic cross~section side view of the piston head and
pressure ng means of the applicator shown in Figure 6 with the pressure
limiting valve closed.
Figure 8 is an enlarged diagrammatic cross-section side view of the piston head and
pressure ng means of the applicator shown in Figure 6 with the pressure
limiting valve means open, and fluid flowing into the barrei of the applicator.
Brief Description of red Embodiments of the invention
Referring first to Figures 1, and 2, an applicator according to one ment of the present
invention is generally referenced by arrow 100.
The applicator 100 has a barrel 1 with an outlet 2. A one way outlet valve 3 is provided at or
adjacent the barrel outlet 2. The barrel outlet 2 is in selective fluid communication with an
applicator outlet 4 from which fluid is discharged in use. In other embodiments (not shown) the
one way valve 3 may be provided at or adjacent the applicator outlet 4.
A piston or plunger 5 is located within the barrel 1 and has sealing means 6, for e an O-
ring seal, to sealingly engage an inner surface 7 of the barrel 1.
In the embodiment shown the piston 5 has an integral hollow pushrod 8 and a ntially
cylindrical head 9 that travels along the cylindrical barrel.
The piston 5 is provided with a pressure limiting means, generally referenced by arrow 10.
In the embodiment shown, the pressure limiting means 10 comprises a flexible diaphragm 11
ted to a valve means, lly referenced 12. The valve means 12 is provided inside
the hollow pushrod 8, the hollow pushrod providing a conduit 13 between a fluid inlet 14 and an
inlet 15 to the barrel. In the embodiment shown, a one way valve means 15a is provided to
prevent flow from the barrel 1 towards the inlet 14.
The diaphragm 11 is preferably annular in shape, and is clamped (and sealed) to the piston
head 9 by clamping means 16.
A force transfer component 17 is provided which consists of an outer ring or hub 18 provided in
front of the agm 11, and an inner hub 19, with the two being connected by several spokes
. The spokes 20 allow fluid to pass through the component 17.
The valve means 12 comprises a valve stem 21 ted to a valve head 22.
The force er component 17 is connected to the valve stem 21 by suitable connecting
means, for example screw 23. The connection between the force transfer component 17 and
the valve stem 21 may have a degree of flexibility, to allow for misalignment between the parts
without upsetting correct operation. in some embodiments the valve stem 21 may be able to
slide through force transfer component 17 without moving the latter with it, but the force transfer
component 17 cannot move d (i.e, further into the barrel) without contacting screw 23 and
also moving the valve stem 21, and thereby opening the valve 12.
A valve seat 24 and spacer 25 are fixed in place in the plunger t. O-ring seals 26 prevent
e past the spacer 25 and valve seat 24.
The valve head 22 is provided with a suitable sealing means, preferably an O-ring seal 27. The
valve head 22 seals against the valve seat 24 when in a closed position (as shown in Figure 2).
The valve head 22 is preferably frusto-conical in shape, and the valve seat 24 is preferably a
complimentary shape.
A valve travel limiting means. for example one or more fins or tabs 28, is arranged to limit the
travel of the valve head 22. in the ment shown the tabs 28 contact spacer 25 when the
valve head 22 has moved a ermined maximum distance away from the valve seat 24.
A biasing means, for example spring 29, urges the valve head 22, and the components
connected to the valve head, including the force er component 17, in the upstream
direction.
A vent means 30 may be provided in the piston head 9 to ensure that the side of the diaphragm
11 which is not in contact with the fluid in the barrel is maintained at ambient atmospheric
pressure.
in the embodiment shown the relationship between the force transfer component 17 and the
diaphragm 11 is such that a clearance space 31 is maintained between them when the
diaphragm 11 is in its relaxed state, as shown in Figure 2. This occurs when the valve 12 is
closed and the pressure inside the barrel 1 is substantially equal to atmospheric pressure (as
shown). This allows spring 29 to bias valve head 22 and O-ring 27 against the valve seat 24
without interference.
In some embodiments guide means (not shown) may be provided to ensure that the vaive stem
21 remains on-centre at its d end.
Figure 2 shows the positions of the components when the pressure inside the barrel 1 is
substantially equal to atmospheric re. The diaphragm it is in its relaxed position, and
the valve 12 is held closed by spring 29.
The force of spring 29 is sufficient to hold valve 12 closed against the pressure of the fluid in the
conduit 13, even if the fluid reservoir (not shown) which supplies fluid to the fluid inlet 14 is
raised a limited distance above the applicator 100.
When the user operates the actuating means (handles 32 in the embodiment shown) to drive
the piston 5, the piston 5 is pushed fonNards and displaces fluid which flows through the one-
way outlet valve 3 and out through the outlet 4. The force ed to open the outlet valve 3
causes the pressure inside the barrel 1 to rise above atmospheric re. in the embodiment
shown the one way valve 15a prevents this pressure from g the diaphragm 11 rearvvards
against the piston 5. The agm 11 does not move from the position shown in Figure 2
during this phase of operation. Valve 12 is still held closed by spring 29.
in preferred embodiments the outlet valve 3 is configured to open under a lower pressure than
the outlet valves of conventional applicators. This reduces the pressure of the fluid within the
barrel during the application stroke, and hence reduces the required hand e force on the
handles 32.
When the user releases the handles 32, a biasing means, for example a handle spring 33
provided inside the handles 32, pulls the piston 5 reanrvards. This induces a partial vacuum
inside the barrel 1, which is communicated to the diaphragm 11 through the inlet 15 and one
way valve 15a.
Air pressure acting on the rd-facing side of the diaphragm 11 pushes the agm
forwards, closing clearance space 31. The diaphragm 11 then pushes forwards against the
force transfer component 17. When the pressure of the fluid in the barrel 1 is low enough, the
force ted by the diaphragm 11 overpowers the spring 29 and moves the valve head 22
away from the valve seat 24, as shown in Figure 3, thereby allowing fluid to flow through the
valve 12.
The distance that the valve 12 opens depends (amongst other things) on how low the pressure
in the barrel 1 is. The valve 12 may open fully, or only part-way. In some embodiments the
stiffness of the diaphragm 11 may cause it to act like a spring, adding to the biasing force
created by spring 29.
Figure 3 shows the ly with the diaphragm 11 deflected and the valve 12 fully open. This
occurs when the piston 5 is being retracted and the barrel 1 is filling with fluid through the valve
12 and inlet 15.
At the end of the barrel refilling stroke the piston 5 contacts a fixed stop. The stop is typicaily
part of a le dosage control means. Suitable dosage control means are known to the art,
and include that described in the applicant’s New Zealand patent number 521084, the contents
of which are included herein by reference.
The momentum of the fluid flowing in the conduit 13 and in the upstream supply tube (not
shown) may tend to keep the fluid moving past the valve 12 and into the barrel 1, even though
the spring 29 is acting on the valve head 22 to try to close the valve 12. If this occurs, the
pressure in the barrel 1 rises and the diaphragm 11 moves rearward, pulled back by the spring
29 acting on the diaphragm via the force transfer component 17.
The valve 12 returns to its substantially closed position before the rising pressure in the barrel 1
reaches atmospheric pressure. Closure of the valve 12 may result in a pressure pulse (from
water hammer) in the conduit 13 and the ing supply tube. However, the force of the
1O spring 29 may be sufficient to keep the valve 12 substantially ciosed despite the momentary
increase in pressure caused by the pressure pulse. Since the pressure pulse cannot pass the
closed vaive 12, the problem of fluid discharging from the nozzle at this time is avoided. Since
the valve 12 is opened by the diaphragm 11 when necessary, the spring 29 may be ed to
provide a larger biasing force than that used by the applicators of the prior art.
Assuming that there are no leaks, the pressure in the barrel 1 remains slightly below
heric re. Because no more fluid can pass the closed valve 12, the diaphragm 11
may remain deflected slightly forwards, ng the force transfer component 17 (i.e. the
clearance space 31 is closed).
Those skilled in the art will appreciate that although the pressure in the barrel 1 of the
embodiment described above is below atmospheric at the end of the inlet stroke, other
ments may be configured such that the pressure is at or above atmospheric pressure at
that stage. in particular, the water hammer pressure pulse may be large enough to force a
small volume of fluid past valve 12, preventing the valve from closing fully, or even ing it
slightly, despite the biasing force of the spring 29. The passage of this small volume of fluid will
displace the diaphragm rearward, reopening a gap between the force transfer component 17
and the diaphragm 11. There may be a corresponding rise in the pressure of the fluid in the
. While this pressure rise may be mitigated by the increase in available volume caused by
the deflection of the diaphragm, in some stances the pressure may rise to above
atmospheric pressure. r, as long as the pressure within the barrel is not high enough to
force the outlet valve 3 open, there will be no unwanted discharge of fluid.
Those skilled in the art will also appreciate that while the invention described above uses a
le diaphragm, in some embodiments part or all of the diaphragm component may be
substantially rigid, ed the diaphragm component can be sealed against the piston head 9
and is able to move to a sufficient degree to actuate valve 12.
While the pressure ng means 10 is shown integrated into the piston 5 in the embodiment
described above, in other embodiments (not shown), particularly those in which space is d,
the pressure limiting means may be provided upstream of the barrel inlet. However, it is
red that the diaphragm be in at least selective fluid communication with the fluid in the
barrel.
Referring next to Figures 4 and 5, a second embodiment of the ion is described, with
similar reference numerals referring to similar components as in Figures 1 to 3.
in the embodiment shown in Figures 4 and 5 the valve means 12 is ed with a hollow valve
stem 34. The hollow valve stem 34 has one or more openings 34a on the downstream side of a
valve head 35. The valve stem 34 extends past valve head 35 to a balancing valve head 36.
The hollow valve stem 34 provides a conduit between the opening(s) 34a and a r 37 on
the upstream side of the balancing valve head 36. The chamber 37 is defined by a balancing
cylinder formation 38. The balancing cylinder formation 38 has a bore 39 with a substantially
cylindrical portion 40 leading into an inwardly tapering portion 41, as shown. The balanclng
cylinder formation 38 is provided within the hollow pushrod 8. In the embodiment shown the
formation 38 is held within the conduit by radial fins 42, and is fixed in place. Fluid is able to
flow freely past fins 42 and into a chamber 43 which is upstream of valve seat 24.
The balancing valve head 36 (which is typically provided with a sealing means such as an O-
ring 44) is fixed to the hollow valve stem 34.
The ion of the embodiment shown in Figures 4 and 5 differs from the operation of the
embodiment shown in s 1-3 as follows.
The hollow valve stem 34 ensures that the pressure in chamber 37 remains close to the
pressure ately downstream of valve head 35, which is in turn approximately equal to the
pressure within the barrel 1.
in this way the resultant force from the pressure difference across valve head 35 is essentially
balanced by the resultant force from the pressure difference across valve head 36. This greatly
s the tendency for valve head 35 to open under the influence of a pressure pulse in
chamber 43, as the pressure also acts on the forward facing side of valve head 36, creating a
substantially equal and te force. This means that the opening of valve head 35 is
controlled ily by diaphragm 11, and reduces the influence of the pressure of the fluid on
the upstream side of valve head 35.
In the embodiment shown in Figure 4 and 5, the balancing valve head 36 has a slightly larger
diameter than valve head 35. This means that raised pressure in chamber 43 will actually tend
to close valve head 35 more firmly.
To reduce friction, O~ring 44 may not be designed to seal within the cylindrical portion 40 of the
balancing cylinder 38. The O-ring seal preferably has only a light interference fit, or a small
nce. Leakage past O-ring seal 44 flows through the hollow valve stem 34 and into the
barrel 1. When valve head 35 is closed, O-ring 44 seals in the conical bore 41 of the balancing
cylinder formation 38 to t leakage.
In an alternative embodiment (not shown) the valve stem 34 may be solid, or may not allow fluid
communication between the chamber 37 and the conduit downstream of valve head 35. in such
an embodiment a separate conduit may be provided to balance the re in the chamber 37
with that immediately downstream of valve head 35.
It is noted that the embodiment shown in Figures 4 and 5 does not have a te component
on the downstream side of the piston 5 which carries a one way valve 15a. In this embodiment,
the barrel inlet 15b is in the head of the plunger 5. However, in other alternatives the
embodiment shown in Figures 1-3 may be used without a te one way valve 15a, and the
embodiment shown in Figures 4 and 5 may be used with a separate one way valve 15a.
While the embodiments shown and described above have a barrel inlet integrated in the piston
or plunger, and a barrel outlet provided in an end wall of the barrel, in other embodiments the
position of the inlet and outlet may be reversed, while in still further embodiments both the barrel
inlet and barrel outlet may be provided at or adjacent the end wall of the barrel.
ing next to Figures 6-8, a further embodiment of the invention is shown which is a
variation on the embodiment shown in Figures 1-3.
In this embodiment the outlet valve 3 is of a type commonly known as an umbrella valve,
selected because of its ability to open at relatively low pressure and therefore reduce the
squeeze force required to be applied to handles 32. A valve incorporating a spring, as shown in
Figure 1, could be used instead.
In this embodiment piston 5 has a hollow shaft 8 with fluid passage 13 and a substantially
cylindrical piston head 50. O-ring 6 seals the piston head 50 within the barrel. A felt washer 51
is preferably provided on the atmospheric side of the O—ring seal 6. The washer 51 is soaked in
oil and provides lubrication.
The barrel inlets 15 are provided by apertures in the piston head 50, and provide a fluid
passage into the barrel. In this ment the one way valve 15a is a valve disc which is held
in place by a pin 52.
The piston shaft 8 is fitted with jet component 53 which defines an orifice 54 for fluid to flow into
a cavity ed in the piston head 50.
An r diaphragm 11 is clamped to the piston 5 by a clamp ring 58, held in place by integral
clips 59. The clips 59 pass through apertures 30 in the piston 5. These apertures 30 also
2O provide venting to one side of the diaphragm 11.
A force transfer component 55 has an outer ring or hub 18 which is (in this figure) ted
from the diaphragm 11 by clearance space 31. The force transfer component 55 has multiple
spokes 20 which connect the outer hub 18 to an inner portion 56 which carries a g washer
57.
A spring 29 biases the force transfer component 55 and the sealing washer 57 against the jet
53, blocking the orifice 54. in this way the sealing washer 57 functions as a valve head 22, and
the end of the jet component 53 functions as a valve seat 24.
A ity of radially inwardly extending fins 60 define a guide for the spring 29 and the force
transfer ent 55. The fins 60 may also limit the maximum travel of the force transfer
ent 55, when the outer rim 18 contacts the fins 60. in this way the fins 60 may limit the
opening of the sealing washer 57 from the jet component 53, thereby limiting the flow rate of
fluid 61 travelling through the inlet conduits into the barrel. By limiting this fiow rate, the
magnitude of the re pulse created at the end of the barrel refilling stroke may be limited.
As with the embodiment shown in Figures 1~3, the use of the agm 11 to provide an
opening force on the sealing washer 57 means that the spring 29 can be configured to provide a
relatively high closing force, thereby reducing the likelihood that the pressure pulse created
when the piston reaches the end of the refilling stroke will pass into and through the barrel. The
ability of the diaphragm itself to deflect (effectively increasing the volume of the inlet conduit),
thereby absorbing any small amount of fluid which the pressure pulse does force past the
pressure limiting means valve head, also reduces the likelihood that fluid will leak from the outlet
valve, even if the fluid pressure required to open the outlet valve is low ed to the
ators of the prior art.
Unless the context clearly requires otherwise, throughout the description and the ciaims, the
words "comprise , comprising”, and the iike, are to be construed in an inciusive sense as
opposed to an exclusive or exhaustive sense, that is to say, in the sense of "inciuding, but not
limited to”.
Where in the foregoing description, nce has been made to specific components or
2O integers of the invention having known equivalents, then such equivalents are herein
incorporated as if dually set forth.
Although this invention has been described by way of example and with reference to le
embodiments thereof, it is to be understood that modifications or improvements may be made
o without departing from the spirit or scope of the invention.
Claims (20)
1. An applicator comprising: a fluid supply inlet; an outlet; a barrel having a barrel outlet and a barrel inlet which is in fluid communication, or selective fluid communication, with the fluid supply inlet; a one way outlet valve in fluid communication with the barrel outlet and with the outlet; 10 a piston le relative to the barrel and in sealing engagement with the barrel; piston actuation means for moving the piston ve to the barrel; the applicator further comprising pressure limiting means for limiting a maximum pressure of fluid ng the barrel from the fluid supply inlet.
15 The applicator of claim 1 wherein the pressure limiting means is configured such that the fluid entering the barrel has a pressure which is at or below an t atmospheric pressure.
The applicator of claim 1 or 2, wherein the pressure limiting means is configured such 20 that the fluid entering the barrel has a pressure which is at or below a pressure required to open the outlet valve.
The applicator of claim 1, 2 or 3 wherein the pressure limiting means is provided at or adjacent the barrel inlet.
The applicator of claim 4 wherein the pressure limiting means is integral with the piston.
The applicator of claim 1 wherein the pressure limiting means comprises a diaphragm.
30 The applicator of claim 6 wherein a first side of the agm is in fluid communication, or selective fluid ication, with fluid in the barrel.
The ator of claim 7 wherein an opposite second side of the diaphragm is exposed to ambient atmospheric pressure.
9. The applicator of any one of claims 6 to 8 wherein displacement of the diaphragm changes an internal volume of a conduit supplying fluid to the barrel inlet.
10. The applicator of any one of claims 6 to 9 wherein the diaphragm is carried by the
11. The applicator of any one of claims 6 to 10 provided with a one way valve means for preventing fluid flow from the barrel though the barrel inlet. 10
12. The applicator of any one of claims 6 to 10 n the pressure limiting means is d to prevent fluid flow from the barrel inlet to the fluid supply inlet.
13. The applicator of any one of claims 6 to 12 wherein the pressure limiting means comprises a first valve head and a first valve seat, wherein the first valve head can be 15 moved from a closed position to an open position by movement of the diaphragm.
14. The applicator of claim 13 n the pressure limiting means comprises a second valve head and second valve seat, wherein the second valve head is connected to the first valve head and moves with the first valve head.
15. The applicator of claim 14 wherein a pressure difference across said first valve head is substantially equal to a pressure difference across said second valve head.
16. The applicator of claim 15 wherein the pressure difference across said first valve head 25 creates a resultant force in a first direction and the pressure difference across said second valve head creates a ant force in a second direction which is opposite to the first direction.
17. The applicator of claim 16 wherein the resultant forces are substantially equal.
18. The applicator of claim 16 wherein the resultant force on the second valve head is greater than the resultant force on the first valve head.
19. An applicator system comprising an ator and fluid supply conduit, the applicator 35 comprising: a fluid supply inlet; an outlet a barrel having a barrel outlet and a barrel inlet in fluid communication, or selective fluid communication, with the fluid supply inlet; a one way outlet valve in fluid communication with the barrel outlet; a piston moveable ve to the barrel and in sealing engagement with the barrel; piston actuation means for moving the piston ve to the barrel; the fluid supply conduit having an inlet and an outlet which is in fluid communication, or selective fluid communication, with the fluid supply inlet of the applicator; 1O the system further comprising pressure limiting means for limiting a maximum re of fluid entering the barrel in use.
20. An applicator substantially as herein described with reference to any one of
Publications (1)
| Publication Number | Publication Date |
|---|---|
| NZ608686B2 true NZ608686B2 (en) | 2015-02-03 |
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ID=
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