Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
10~9740
This invention relates generally to valve mechanisms, and
more particularly to an improved valve mechanism which combines the
functions of pressure regulating and fluid flow control. The combination
pressure regulating and flow control valve of the present invention is
adapted for many uses as, for example, for controlling the operation of an
air cylinder in either one direction or both directions.
It is known in the valve art to provide pressure regulation to
individual or multiple directional control valves with single or multiple
pressure regulators to control the pressure supplied to the device being
10 controlled. The use of multiple pressure regulators is expensive and awk-
ward requiring special directional control valves and excessive piping.
Where multiple directional valves are mounted in stacking fashion or on a
common manifold base, it is extremely difficult and expensive to provide
pressure regulation to individual outlets. It is not common to use such
pressure regulators in the line between the outlet or cylinder port of the
directional valve and the device being controlled because of cost, space and
the relatively short life of diaphragms and other components of pressure
regulators. It is common to provide flow control means in the line between
the directional control valve and the device being controlled, Because of
20 cost, complexity and space requirements it has not?been practicable in
the past to provide both pressure regulator means and flow control means
between the cylinder port of the directional control valve and the device
being controlled. The result has been a waste of air requiring excessive
pumping capacity, a waste of energy, and increase in the cost of using air
as a power and control means,
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In accordance with the present inv~ntion, a combination pres-
sure regulating and llow control valve is provided which can be installed
in any cylinder or actuation line to control both the pressure and the flow
of air in that line. The combination valve of the present invention in-
cludes an adjustable pressure regulator valve means which is constructed
and arranged to regulate the supply pressure to an air cylinder being con-
trolled by the valve of the present invention. The valve of the present in-
vention also includes an adjustable flow control valve for controlling the
flow of air to or from the air cylinder being controlled by the valve. A
10 spring biased check valve is in parallel with the adjustable pressure regu-
lator valve and it is operable to provide return flow through the valve from
a wide open or free flow condition to a metered out flow condition in cooper-
ation with the adjustable flow control valve. In one embodiment, the adjust-
able flow control valve means may also be used in series with the adjust- -
able pressure regulator valve means to provide either a metered in or
metered out condition, with pressure regulation and flow control, and a
free flow out or free flow in condition, respectively. Said one embodiment
of the adjustable flow control valve means can also be adjusted to provide
both a free flow in condition and a free flow out conditionJ without flow con-
20 trol, and with pressure regulation provided by the adjustable pressure
regulator valve means. In a second embodiment, the adjustable flow con-
trol valve means can further provide both a metered in condition and a
metered out condition, with pressure regulation provided by the adjust-
able pressure re~ulator valve means~
The combined pressure regulating and flow control valve of
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the present invention overcomes the disadvantages of the aforementioned
prior art structur~s in that no separate pressure regulating device is re~
quired to reduce the pressure down to a required lower operating pressure,
whereby a saving of air is provided at a minimum of cost. The pressure
re,gulating and flow control valve of the present invention also provides a
control over the speed of an air cylinder, whereby the air cylinder may be
efficiently operated in either direction and at a savings of air, The valve
of the present invention is advantageous in that it provides in one compact
and economical unit the combined functions of pressure regulating and flow
1 0 control.
~; The combination pressure regul~ing and flow control valve of
i the present invention also i~cludes quick exhaust function which provides a
quick dump exhaust characteristic in addition to the pressure regulating
and flow control characteristics.
Other features and advantages of this invention will be appar-
ent from the following detailed description, appended claims,, and the
accompanying drawings.
In the drawings:
, : ;
Fig, 1 is a top plan view of a ~irst embodiment of a combina-
20 tion quick exhaust and flow control valve.
Fi~ 2 is an elevation section view of the valve structure illus-
trated in Fig. 1, taken along the line 2-2 thereof, looking in the direction
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of the arrows, and showing a meter out function.
Fig. 3 is a top plan view of the valve body structure illus-
trated in Fig. 2, taken along the line 3-3 thereof, and looking in the direction
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of the arrows.
Fig. 4 is an elevation section view of the valve structure illus-
trated in Fig. 3, taken along the line 4-4 thereof, and looking in the
direction of the arrows.
Fig. 5 is a bottom view of the valve body illustrated in Fig. 2,
taken along the line 5-5 thereof, and looking in the direction of the arrows.
Fig. 6 is a fragmentary, elevation section view of the embodi-
ment of Figs. 1-5 adjusted to provide a meter in function.
Fig. 7 is a fragmentary, elevation section view of a second
embodiment of the invention, and showing a meter out function.
Fig. 8 is a fragmentary, elevation section view identical to
Fig, 7, and showing the valve structure of the second embodiment adjusted
to provide a meter in function.
Referring now to the drawings, and in particular to Figs. 1
and 2, the numeral 10 generally designates a first illustrative embodiment
of a combination pressure regulating and flow control valve, with quick ex-
haust, made in accordance with the principles of the present invention. The
valve 10 includes a valve body 11, a top end cover 12, and a bottom end
cover 13. A suitable gasket 16 is disposed between the valve body 11 and
both of the end covers 12 and 13. The top end cover 12 is secured to the
valve body 11 by any suitable meansJ as by suitable machine screws 14.
The bottom end cover 13 is secured to the valve body 11 by any suitable
means, as by suitable machine screws 15. The valve body 11 is provided
with a supply or upstream pressure port 20 which communicates with an in-
wardly extended passageway 21 which is formed in the valve body 11.
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A vertical valve bore 22 is formed in the valve body 11, and
it is disposed perpendicular to the passageway 21. A pressure regulator
valve, generally indicated by the numeral 23, is operatively mounted in
the bore 22. The bore 22 communicates at its lower end with an interior
lower passageway 24 which is formed by the combined structure of the valve
body 11 and the bottom end cover 13. The interior lower passageway 24
communicates through a bore 25 with an interior upper passageway or
chamber 26 which in turn communicates with a downstream port 28 A
double acting, adjustable fluid flow control means, generally indicated by
10 the numeral 27, is operatively mounted through the bore 25, The double
acting, adjustable fluid flow control means 27 includes a pair of floating
needle valves, which are described more fully hereinafter, and which are
adapted to function alternately for flow control purposes with two valve
seats 29 and 30 which a~e formed at the orifices ~t the upper and lower
ends of the bore 25.
As shown in Fig. 4, an adjustable quick exhaust and check
valve, generally indicated by the numeral 35, is operable for communi-
cating the downstream port 28 with the upstream port 20. A bore 32
communicates the interior passageway 21 with a lower interior exhaust
20 chamber or passageway 33" which is formed by the combined structure
of the valve body 11 and the bottom end cover 13. The lower interior ex-
haust chamber 33 communicates with the upper interior chamber or pas-
sageway 26 through a connecting passageway 34.
The pressure regulator valve 23 is shown in detail in Fig 2,
and it is adapted to control the flOw of fluid between the valve bore 22 and
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~he lower interior passageway 24. As shown in Fig. 2, a valve seat 38
is formed at the lower end orifice of the bore 22J at the junction point be-
tween the valve bore 22 and the interior lower chamber 24. An inverted
conical poppet valve element 39 is bonded to the lower portion 40 of a
lower valve stem 48 which is movably mounted in the bore 22 The poppet
valve element 39 terminates at its upper end at an integral, annular flange -
or shoulder 41 and at its lower end at a larger integral annular flange or
shoulder 42, The poppet valve element 39 is lightly biased in the closing
direction toward the valve seat 38 by a suitable spring 44 which is mounted
10 around the enlarged lower end 43 of the valve stem 48. The lower end of
the spring 44 abuts the inner face of the bottom end cover 13. The upper
end of the spring 44 abuts the lower side of the annular shoulder 42.
As shown in Fig. 2, the upper end of the valve stem 48 is pro-
vided with a pair of annular shoulders or flanges 50 which are s~idably .
mounted in theupper end 49 of the bore 22. A suitable seal 51 is mounted
between the shoulders 50. A spring 54 has its lower end mounted in the
bore portion 49 and it is seated around the upper end 52 of the valve stem
48. The spring 54 extends upward into an enlarged diameter bore 53 which
communicates at its inner end with the bore 22, and which is open at the :
20 top en.d of the valve body 11, where it is enclosed by the top end cover 12.
The upper end of the spring 54 is seated around a reduced diameter portion
lower end of a~ adjustable upper valtte stem 59. A radially extended
annular shoulder or flange 58 is integrally formed on the valve stem 59 i n
a position spaced upwardly from the lower end of the valve stem 59, and the .
upper end of the spring 54 abuts against this shoulder. The valve stem 59
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is threadably mounted in a threaded bore 60 formed through the top end
cover 12. The outer end of the valve stem 59 is provided with a suitable
tool slot for adjusting the valve stem 59 with a screw driver or the like.
The valve stem 59 is shown in Fig. 2 in its maximum upward adjusted
position. The valve stem 59 is locked in a desired adjusted position by
a lock nut 61. It will be s~en that the pressure regulator valve is essentially
a balanced spring biased poppet valve. The upper valve stem 59 is ad-
justed downwardly or inwardly to bias the poppet valve element 39 off of
the valve seat 38 totb~ open position to allow a flow of air past the poppet
10 valve element 39 whenever air or other fluid is entering through the in~et
or supply port 20. VVhen flow startsJ the downstream pressure exerts a
force on the area of the poppet valve element 39, exposed to said down-
stream pressure. When such force equals the force exerted by the adjust-
able spring 54 the valve element 39 will close to flow, being urged by the
fixed spring 44 to the closed position on the valve seat 38. It will be under-
stood that the pressure required to move the poppet valve element 39 up-
wardly to the closed position is dependent upon the spring force exerted
thereon by the spring 54. In the closed position, the force of the inlet fluid
pressure is balanced between the inlet valve seat 38 and the pressure
20 balancing seal means 51, Therefore, variations in inlet pressure can
cause only small variations in the downstream pressure.
As shown in Fig. 2, the passageway 21 communicates with a
vertical valve bore 65 which in turn communicates at its lower end through
a bore or passageway 66 with the lower interior passageway 24. A check
or relief valve means, generally indicated by the numeral 64, is oper~tively
)89740
mounted within the valve bore 65 for controlling the flow of air or other
fluid through the bore 66 which is smaller in diameter than the valve seat
38. The check valve means 64 includes a cup-shaped valve body 67 having
an open upper end, and which is made from a suitable elastomeric material,
and provided with a cup-shaped liner 70 that is made from any suitable -
material, as for example, stainless steel. As shown in Fig. 2, a suitable
spring 71 has its lower end mounted within the chamber 69 of the liner 70J
and its upper end extended upwardly and seated against the inner end face
of a plug 72. The plug 72 is threadably mounted in a threaded bore 73 that
10 is open at the upper end of the body 11, and which communicates at its inner
end with the valve bore 65. The cup-shaped valve body 67 is provided on
its closed lower end with an integral, annular, axially extended projection
68 which is adapted to be seated around the upper end of the passageway or
bore 66 for enc~osing the same in a valve closing action. It will be seen
that the spring 71 normally biases the check valve 64 into a closed position,
as shown in Fig. 2, to prevent flow of air or other fluid from the upstream
passage 20 down through the bore 66 into the interior lower passageway 24.
However, when the flow of fluid through the valve is in the reverse direc-
tion, that is from the lower interior passageway 24, the check valve 64
20 would be biased upwardly by the returning fluid flow pressure and moved
to an open position to permit the fluid to exhaust through the bore 66 and in-
to the bore 65, and thence into the passageway 21 and out the port 20, so as
to reduce the pressure in the lower passageway 24 to allow the regulator
valve element 39 to open and provide flow past the regulator valve as well
as past the check valve 64.
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1089~740
As shown in Fig. 2, the double acting, adjustable fluid
flow control means 27 includes an elongated valve stem, generally indi-
cated by the numeral 78, which is vertically disposed in the valve body
11, at right angles to the ports 20 and 28. The valve stem 78 is disposed
so as to extend downwardly through the passageway 25, with its lower
end 77 disposed in the interior lower passageway 2~. An integral, annu-
lar shoulder or flange 79 is formed on the lower portion of the valve stem
78. A lower needle valve 81 is slidably mounted on the lower end portion
77 of the valve stem 78, and it has a conically shaped outer face 88. The
10 needle valve 81 has an axial bore 82 which receives the valve stem portion
77. The needle valve borë 82 communicates with an enlarged bore 86
formed at the lower end of the heedle valve 81. The needle valve 81 is
disposed with its conically shaped outer face 88 facing upwardly, so as to
operate in relation to the lower valve seat 30 at the lower end of the pas-
sage 25. A spring 83 is mounted around the lower end 77 of the valve stem
78, and it has its upper end seated in the enlarged bore 86 formed in the
lower end of the needle valve 81. The lower end of the spring 83 is seated
in a recess 87 formed in the inner face of the bottom end cover 13. The up-
per end of the needle valve 81 is flat, as indicated by the numeral 84, and
20 it is adapted to be normally seated on the flat lower face 85 of the shoulder
79. The spring 83 normally biases the needle valve 81 upwardly into seat-
ing engagement against the lower face 8~ of the shoulder 79.
A second needle valve 92 is provided with an axial bore 93 which
terminates in an enlarged bore 97 at the top end thereof, as shown in Fig.
2. The needle valve 92 is slidably mounted on the valve stem 78, in a
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08974U
position above the shoulder 79. The needle valve 92 is provided with a
conically shaped outer face 91 which is adapted to operate with the upper '
valve seat 29 that is formed at the upper end of the passageway 25, The
front end of the upper needle valve 92 is disposed downwardly in oppo- - ' '
site relationship to the front end of the lower needle valve 81. The front
end of the needle valve 92 is flat, as indicated by the numeral 95, andthis ~lat -,-
Çront.~nd, is adapted to be normally seated on the flat upper face 96 of the
shoulder 79. A spring 94 is mounted around the valve stem 78, in a
position above the needle valve 92, and the lower end thereof ~$: seated in
10 the enlarged bore 97 formed in the rear end of the needle valve 92. The
upper end of the spring 94 is seated in an enlarged bore 98 that is formed ~.
in the lower end of a valve stem retainer which has a large diameter
lower end 99 and a small diameter upper end 108 which extends upwardly
and through a circular opening 109 formed in the top end cover 12,
The valve stem 78 extends upwardly through the enlarged bore .
98 and a communicating reduced diameter bore 113, and thence through a ''
reduced diameter threaded bore 114, in the upper end of the retainer upper
end portion 108. The upper end 80 of the valve stem 78 is threaded, and it
is threadably mounted in the threaded bore 114 for adjusting the valve stem
20 upwardly and downwardly. The valve stem 78 is secured in a desired ad-
justed position by a suitable lock nut 115. The lower end of the retainer
large diameter portion 99 is slidably mounted in a bore 100 that is formed
in the valve body 11 and which communicates with the upper end of the
upper interior passageway 26. The upper end of the retainer large diameter
lower portion 99 is threaded on its periphery, as indicated by the numeral
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106, and it is threadably mounted in the upper threaded portion 107 of
the bore 100. As shown in Fig. 2, a suitable O-ring seal 104 is oper-
atively mounted in a groove formed around the valve stem retainer lower
end portion for operative engagement with the bore 100. An O-ring seal
means 105 is mounted in an internal groove formed in the valve stem re~
tainer lower end portion 99, and it operatively engages the outer periphery
of the valve stem 78.
As shown in Fig. 2, the double-acting, adjustable fluid flow
control means 27 is shown in an adjusted position whereby fluid passing
10 from the lower interior passageway 24 upwardly through the passage 25
and into the upper interior passage 26, and out the port 28, will be carried
in a free flow manner, since the fluid under pressure will m;ove the upper
needle valve 92 upwardly against the pressure of the spring 94 to provide
a free flow action.
When the flow of fluid to the valve 10 is reversed, the fluid
under presaure will engage the top of the needle valve 92, and function with
the spring 94 to maintain the needle valve 92 in the position shown in Fig.
2, with its lower end 95 in seating engagement on the upper shoulder 96
of the flange 79. The returning or exhausting fluid will have to pass be-
20 tween the conical outer face 91 of the needle valve 92 and the upper valveseat 29, in a desired flow control condition, whereby the fluid is metered
out during its return flow through the valve 10, The pressure regulator
valve 23, and the double acting, fluid flow control means 27 are disposed
in Fig. 2 so as to provide free flow in and a meter out function. It will be
understood that when the fluid is exhausting past the needle valve 92 in a
`` 1089~
meter out action, that it will pass down into the lower interior passageway
24 and thence upwardly past the check valve 64 and into the passageway
21 and out the port 20,
Fig 6 shows the fluid flow control valve 27 adjusted upwardly
so as to move the lower needle valve 81 upwardly into an operative re-
lationship with the lower ~Jal~e seat 30, whereby a meter in action is pro-
vided, since the fluid flowing from the lower interior passageway 24 up-
wardly into the upper passageway 26 will function with the spring 83 to
maintain the needle valve 81 in the position shown in Fig. 6 against the
10 shoulder 79. The fluid flowing past the outer conical face 88 of the needle
valve 81 and through the orifice at the valve seat 30 is thus provided with
a meter in function. When the fluid is flowing in the reverse manner through
the structure shown in Fig. 6, the fluid will flow with a free flow out action.
It will be understood that the valve stem 78 may be adjusted downwardly
from the position shown in Fig. 6, so as to move the lower needle valve
81 out of the area of the valve seat 30 into an inoperative position. The
upper needle valve 92 would be in a similar inoperative position raised
above and out of the area of the upper valve seat 29, so as to provide a free
flow of fluid in and out of the valve 10 while passing through the passageway
20 25.
As shown in Fig. 4, the adjustable quick exhaust and check
valve means 35 is operatively mounted in a vertical bore 118 that extends
into the valve body 11 from the upper end thereof, and which communicates
at its lower end with the internal passageway 21. The pass~geway or bore
32 communicates the lower end of the valve bore 118 with the lower
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interior exhaust chamber 33. The adjustable quick exhaust and check
valve means 35 includes a cup-shaped valve body member 119 which is
made from a suitable elastomeric material. The valve body 119 functions
as a check valve, and it is provided with a conically shaped nose 120 which
has a sloping surface 121 that is adapted to be normally seated on a valve
seat 122 that is formed at the upper en~ of the passage 32.
The valve 119 is provided with a cup-shaped liner 127. The
lower end of a spring 128 is seated in the interior chamber 126 of the liner
127. The upper end of the spring 128 is seated around the lower end 129
of an adjustable valve stem, generally indicated by the numeral 134. The
upper end of the spring 128 abuts the lower side of an integral annular
shoulder or flange 130 that is formed on the lower or inner end of the valve
stem 134. A second integral annular shoulder 132 is formed on the valve
stem 134 in a position spaced apart from the shoulder 130 to form a groove
131 therebetween in which is operatively seated an O-ring seal 133, The
O-ring seal 133 ;o.perati~ ély engages the surface of the bore 118.
The valve stem 134 is threadably mounted in a ~,hreaded bore
135 which is formed.through the top cover 12, and which communicates with
the upper end of the valve bore 118 in the valve body 11. The valve stem
134 is secured in a desired adjusted position by a suitable lock nut 136. It
will be seen that the valve stem 134 can be~ adjusted inwardly from its maxi-
mum raised position shown in Fig. 4, so as to ~xert a desired spring pres-
sure on the cup-shaped check valve 119 to control the fluid pressure under
which the valve 119 will open to allow fluid to exhaust from the port 28 and
through the passageways 34, 33 and 32, and into the passageway 21 and out :
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1089'740
the port 20.
In use, the combination p~ressure regulating and flow control
valve means 10 illustrated in Figs. 1 through ff is adaL~ted to provide a
pressure regulating function when the fluid flow is in one direction, and a
metering out or flow control function when the fluid flow is in the other
direction. With supply air flowing into the chamber 21 through the port 20,
the air is blocked by the check valve 64 from passing through the passage-
way 66, but It is permitted to flow downwardly through the bore 2 2 into
the interior lower passageway 24 because the valve 23 is adjusted so that
10 the poppet valve element 39 is in an open position to allow flow into the
passageway 24, The air cannot pass from the chamber 21 past the quick
exhaust valve 35 since this valve acts as a check valve. The air in the
lower interior passageway 24 passes upwardly past the lower needle valve
81 which is in an inoperative position, and upwardly through the passage
25 in a free flow past the upper needle valve 92 into the upper interior
chaErLber 2~ and out the port 28. The pressure of the air flowing through
the passageway 25 moves the upper needle valve 92 upwardly against the
pressure of the spring 94 to an open position to permit the free flow of the
fluid thereby. When the downstream pressure builds up in the lower inter-
20 ior chamber 24 to a predetermined force equal to the force exerted by the
adjustable spring 54, the poppet valve element 39 will be moved to a closed
position by the fixed spring 44.
VVhen air is exhausted into the downstream port 28 and into the
upper interior chamber 26 in a reverse flow, it will force the needle valve
92 downwardly against the shoulder 79, and air will pass downwardly around
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1089~40
the needle valve 92, and through the valve seat 29, to provide a metering
out action on the exhausting air. The air passing down into the lower in-
terior chamber 24 will open the relief or check valve 64 to reduce the
pressure in the lower chamber 24 so that the regulator valve element 39
will open. The quick exhaust valve 35 can be set so as to open at any de-
sired condition, as for example, to quickly reduc~ the pressure in the
chamber 24 to a predetermined level quickly to allow the regulator valve
element 39 to open and thus reduce the pressure quickly on the head end
of a cylinder to start the piston moving back.
It will be seen that the valve stem 78 can be adjusted upwardly
to the position shown in Fig. 6 to provide a metering in function and a free
flow out function. It will also be understood that the valve stem 78 can be
so adjusted to a position wherein the needle valves 81 and ~2 are inoper-
ative to allow free flow past both valves, whereby the valve 10 then per-
mits a free flow in function and a free flow out function, without any meter-
ing action whatsoever. It will be understood that the quick exhaust valve
35 may be adjusted to keep it closed during a meter in function or be ad-
justed as desired to reduce the downstream pressure to a predetermined
level.
It will be seen from the foregoing, that the embodiment of
Figs. 1 through 6 provides a pressure regulating and flow control valve,
wherein a pair of needle valves are movably mounted on a single valve
stem so that they can float in one direction against a spring pressure and
be held against movement in the other direction by a common shoulder on
the valve stem. It will be seen that the embodiment of Figs. ~b through 6
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10~i9~7~
can be adjusted to provide a regulated, free flow in function, with a
meter out function, or a regulated, meter in function with a free flow
out function, or a regulated free flow in function with a free flow out
function. The regulator valve means can be adjusted to provide any of
said free flow and metering functions without the regulating function. An
advantage of the structure of the embodiment of Figs. 1 through 6 is that
all of the seals are in the valve body or in the retainer member, and not
in the top end cover, whereby a s~ructure is provided wherein the critical
dimensions are easily held or met during machining operations on the
10 valve body 11. The last mentioned feature provides a cost advantage,
since the number of parts needed to be handled when machining critical
dimensions is reduced, and the parts handling time is reduced.
Figs. 7 and 8 illustrate a second embodiment of the invention
wherein a pair of flow control needle valves a~:e each mounted on an indi-
vidual valve stem. As shown in Figs. 7 and 89 the parts of the second
embodiment which are the same as parts of the first embodiment of Figs.
1 through 6 have been marked with the same reference numerals followed
by the small letter "a". The numeral 140 ge~lerally designates a first
flow control valve means which is mounted in an upper position while the
20 numeral 141 generally designates a second flow control valve mounted in
an opposed, lower position. The upper flow control valve means 140
includes a needle valve 142 which has an axial bore 143 therethrough for
slidably mounting the needle valve 142 on a valve stem, generally indi-
cated by the numeral 144. The needle valve 142 is provided ~uith a flat
end 146 on the front end thereof, which is adapted to be seated on the flat
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`` lO~Y;~40
upper side 145 of an annular shoulder or flange 149 that is formed on the
lower or inner end of the valve stem 144. The needle valve 142 is pro-
vided with a conically shaped outer face 147 which terminates at its upper
end in'.a tapered shoulder, as compared to the flat shoulders on the needle
valves 81 and 92 in the first embodiment of Figs. 1 through 6. The
needle valve 142 is adapted to operate in relation to a valve seat 148 for
controlling the flow of fluid ~heret~r~ugh,and through the passage 25a.
The needle valve 142 is normally biased downwardly for seat-
ing engagement on the shoulder 149 by a spring 152. The lower end of the
10 spring 152 is seated in an enlarged bore lSl in the upper end of the needle
valve 142. The upper end of the spring 152 is seated in an enlarged bore
153 formed in the top end cover 12a. The valve stem 144 is slidably
mounted in a bore 156 formed in the top end cover 12a, The valve stem
144 has an O-ring 154 operatively mounted in a groove around its per~.phery
for sealing engag~nent with the bore 156. The upper end of the valve stem
144 is threaded, as indicated by the numeral 155, and it is threadably
mounted in a threaded bore 157 which is a continuation of the bore 156 in
the top end cover. The valve stem 144 is adapted to be locked in an adjust-
ed position by a lock nut 158, The numeral 159 designates a snap ring that
20 functions as a stop member to limit the inward adjustment of valve stem
144.
The lower flow control valve means 141 includes a needle .
valve 162 which has an axial bore 163 therethrough for slidably mounting
the needle valve 162 on a valve stem, generally indicated by the numeral
164. The needle valve 162 is provided with a flat front end 166 which is
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adapted to be seated on the flat lower side 165 of the annular shoulder
168 which is formed on the upper or inner end of the valve stem 164, The
needle valve 162 is provided with a conically shaped outer face 167 which
terminates at its lower end in a tapered shoulder, in the same manner
as the needle valve 142. The needle valve 162 is normally biased against
the shoulder 168 by a spring 170 which has its upper end seated in an en-
larged bore 171 formed in the rear end of the needle valve 162. The
other end of the spring 170 is seated in an enlarged bore I72 formed in the
bottom end cover 13a. The valve stem 164 is slidably mounted in a bore
174 in the bottom end cover 13a, The valve stem 164 is provided with a
suitable O-ring seal means 173 for sealing engagement with thebore 174.
The lower end 175 of the valve stem 164 is thr~aded and it extends out of
the bottom end cover 13a, The threaded lower end 175 of the valve stem
164 is threadably mounted in a threaded bore 178, The valve stem 164 is
locked in an adjusted position by a lock nut 176. The numeral 179 desig-
nates a snap ring that functions like snap rlng 159.
As shown in Fig. 7, the second embodiment is positioned with
the upper needle valve 142 in an operative position relative to the valve
seat 148 so as to provide a free flow in function for fluid passing through
20 the valve, and a metering out function on fluid being exhausted through
the valve. The lower needle valve 162 is withdrawn into an inoperative
position to allow free flow past this valve for fluid flowing in either direc-
tion through the valve.
Fig. 8 shows the needle valves 142 and 162 reversed in po-
sition so that the lower needle valve 162 provided a metering in function
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and a free flow out function while the upper needle valve 142 is positioned
in an inoperative position to permit free flow of fluid thereby in each
direction.
The embodiment of Figs. 7 and 8 can carry out the same func-
tions as described hereinbefore for the first embodiment of Figs. 1 through
6, The embodiments of Figs. 7 and 8 can carry out a further function
over the first embodiment in that the needle valves 142 and 162 can both
be moved inwardly to an operative position relative to their respective
valve seats so as to provide both a metering in function and a metering
10 out function.
While it will be apparent that the preferred embodiments of
the invention herein disclosed~ewell calculated to fulfill the objects above
stated, it will be appreciated that the invention is susceptible to modifi-
cation, variation and change.
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