U.S. patent application number 10/895362 was filed with the patent office on 2005-04-07 for self-contained hydraulic esd system.
This patent application is currently assigned to Argus Machine Co. Ltd.. Invention is credited to Ellett, James Richard.
Application Number | 20050072473 10/895362 |
Document ID | / |
Family ID | 27671964 |
Filed Date | 2005-04-07 |
United States Patent
Application |
20050072473 |
Kind Code |
A1 |
Ellett, James Richard |
April 7, 2005 |
Self-contained hydraulic ESD system
Abstract
A hydraulic control circuit, comprising a control line connected
to a device to be controlled by fluid pressure in the control line;
a time-out valve on the control line, the time-out valve having a
time-out period during which time-out period operation of the
time-out valve is delayed after actuation of the time-out valve; a
pump connected to the control line for pressurizing the control
line with fluid; and an arming valve operated by pressure on an
arming line connected to the control line and the arming valve
being connected to the time-out valve to reduce the time-out period
in response to pressure on the control line.
Inventors: |
Ellett, James Richard;
(Edmonton, CA) |
Correspondence
Address: |
THOMPSON LAMBERT
SUITE 703D, CRYSTAL PARK TWO
2121 CRYSTAL DRIVE
ARLINGTON
VA
22202
|
Assignee: |
Argus Machine Co. Ltd.
Edmonton
CA
|
Family ID: |
27671964 |
Appl. No.: |
10/895362 |
Filed: |
July 21, 2004 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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10895362 |
Jul 21, 2004 |
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10079832 |
Feb 22, 2002 |
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6772786 |
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Current U.S.
Class: |
137/488 |
Current CPC
Class: |
F15B 20/00 20130101;
Y10T 137/7762 20150401; Y10T 137/7764 20150401; F15B 13/10
20130101; F15B 21/10 20130101 |
Class at
Publication: |
137/488 |
International
Class: |
F16K 031/12 |
Foreign Application Data
Date |
Code |
Application Number |
Feb 20, 2002 |
CA |
2,372,760 |
Claims
1-12. (cancelled)
13. A hydraulic control circuit, comprising: a control line having
an inner diameter; and a restrictor on the control line, the
restrictor comprising plural loops of continuous tubing arranged in
plural layers, the tubing having a smaller inner diameter than the
control line.
14. The hydraulic control circuit of claim 13 in which the layers
are spirally wound.
15. A hydraulic control circuit, comprising: a control line
connected to valve actuator; a time-out valve on the control line,
the time-out valve having a time-out period during which time-out
period operation of the time-out valve is delayed after actuation
of the time-out valve; a pump connected to the control line for
pressurizing the control line with fluid; and an arming valve
operated by pressure on an arming line connected to the control
line and the arming valve being connected to the time-out valve to
reduce the time-out period in response to pressure on the control
line.
16-17. (cancelled)
Description
BACKGROUND OF THE INVENTION
[0001] This invention relates to hydraulic emergency shut-down
systems (ESD) for actuating closure of valves.
[0002] U.S. Pat. No. 6,276,135 issued Aug. 21, 2001, and Canadian
application no. 2,266,806 published Sep. 23, 2001, describe a
hydraulic control circuit for a hydraulic actuator, including a
high-low pilot valve having a sensing port for connection to a flow
line. When the sensed pressure from the flow line moves outside of
a pre-set operating range, the hydraulic actuator is actuated and
flow in the line is stopped. For initiating the operation of the
high-low pilot, a time out valve is closed on the hydraulic control
circuit to allow manual build up of pressure in the hydraulic
control circuit to the operating range. This opens the hydraulic
actuator and the high-low pilot maintains pressure on the hydraulic
circuit to keep the hydraulic actuator open.
[0003] A difficulty occurs with this hydraulic control circuit in
that there may be a period in which the time-out valve is closed,
but the hydraulic actuator is open, so that there is fluid flow in
the flow line, with no way to monitor the pressure in the flow
line.
SUMMARY OF THE INVENTION
[0004] This invention is directed to providing increased safety of
operation of a self-contained hydraulic emergency shut down
system.
[0005] Therefore, according to an aspect of the invention, there is
provided a hydraulic control circuit, comprising a control line
connected to a device to be controlled by fluid pressure in the
control line; a time-out valve on the control line, the time-out
valve having a time-out period during which time-out period
operation of the time-out valve is delayed after actuation of the
time-out valve; a pump connected to the control line for
pressurizing the control line with fluid; and an arming valve
operated by pressure on an arming line connected to the control
line and the arming valve being connected to the time-out valve to
reduce the time-out period in response to pressure on the control
line.
[0006] The hydraulic control circuit has particular utility for use
with a flow line and the device to be controlled is a valve on the
flow line.
[0007] In a further aspect of the invention, the time-out valve
includes a restrictor on a fluid return line that regulates the
time-out period. The restrictor may comprise plural loops of
continuous tubing arranged in plural layers, preferably spirally
wound, the tubing having a smaller inner diameter than the fluid
return line. In a further aspect of the invention, the arming valve
operates a bypass around the restrictor. In a further aspect of the
invention, the time-out valve is normally open, and is closed after
actuation until expiry of the time-out period.
[0008] In addition, this invention provides a novel configuration
of bias restrictor for use on a control line on a hydraulic
circuit. The restrictor comprises plural loops of continuous tubing
arranged in plural layers, preferably spirally wound, the tubing
having a smaller inner diameter than the control line.
[0009] These and other aspects of the invention are described in
the detailed description of the invention and claimed in the claims
that follow.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] There will now be described preferred embodiments of the
invention, with reference to the drawings, by way of illustration
only and not with the intention of limiting the scope of the
invention, in which like numerals denote like elements and in
which:
[0011] FIG. 1 is a hydraulic schematic of a hydraulic control
circuit according to the invention; and
[0012] FIGS. 2A and 2B are sections through restrictors for use in
hydraulic control circuits and particularly in the hydraulic
control circuit of FIG. 1.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
[0013] In this patent document, a reference to "a connection",
"connected" or "connect(s)" is a reference to hydraulic connection
unless the context otherwise requires. In this patent document, the
word "comprising" is used in its non-limiting sense to mean that
items following the word in the sentence are included and that
items not specifically mentioned are not excluded. The use of the
indefinite article "a" in the claims before an element means that
one of the elements is specified, but does not specifically exclude
others of the elements being present, unless the context clearly
requires that there be one and only one of the elements.
[0014] Referring to FIG. 1, there is shown a hydraulic control
circuit for an actuator 20, which actuates a valve, not shown. A
high-low pilot valve 10 is connected to a flow line 16 to be
monitored through port 12 of valve 10 and line 14 through isolation
valve 15. A single pressure line or hydraulic manifold 18 connects
the high-low pilot 10 to the hydraulic actuator 20. The single
pressure line 18 has a single pressure along its length, and thus
forms a single pressure circuit. A second line 22 connects the
high-low pilot 10 to a reservoir 24. A normally closed relief valve
26 is connected to the single pressure line 18 through line 28 for
relief of excessive pressure and drains through line 27 and line 22
to the reservoir 24. A normally closed override valve 30 is
connected to the single pressure line through line 28 and 29 for
manual override of circuit controls. The line 28 connects to the
line 18 between a time out valve 44 and actuator 20. The override
valve 30 drains through line 31 and 22 to the reservoir 24. A pump
32 is connected to the single pressure line 18 via line 34 and line
28 for pressuring the single pressure line. The pump 32 is
preferably a hand pump, and is separated from the line 28 by a
filter 36 and a leak tight outlet check valve 38, both on line 34.
The pump 32 is also connected via line 40 with inlet check valve 42
to reservoir 24. A fusible plug 48 for relief of pressure eg during
fires is also provided on line 18.
[0015] When the pump 32 is activated, fluid moves from reservoir 24
through lines 40, 34 and 28 into line 18. The relief valve 26 and
override valve 30 block return of fluid to reservoir 24, and thus
pressure builds up in line 18 when the pump 32 is activated. The
time out valve 44 is normally open, and is set to close a pre-set
time interval after being manually activated.
[0016] The hydraulic control circuit works as follows. The high-low
pilot 10 monitors pressure in the flow line 16 and is normally
closed. When the pressure exceeds a high set point or is lower than
a low set point, the pilot valve 10 opens, and hydraulic fluid
drains from line 18 and 22 into reservoir 24. Loss of pressure at
the actuator 20 causes the actuator 20 to close its associated
valve. If the pressure in lines 28 or 18 becomes too high itself,
then relief valve 26 opens, until the pressure returns to normal.
The actuator 20 can be activated manually by operation of the
override valve 30. If the temperature becomes too high, fusible
plug 48 opens to allow line 18 to drain and activate the actuator
20. Fusible plug 48 may be connected by a line (not shown) to
discharge to the tank 24.
[0017] To set the actuator 20 initially, pressure must be built in
line 18. This is accomplished initially by manually closing time
out valve 44. High low pilot 10 is open with low line pressure
being sensed. The time out valve 44 begins to count down towards
opening. While time out valve 44 is closed, pump 32 is activated to
increase the pressure in lines 18 and 28 until actuator 20 is
activated. Activation of actuator 20 will lead to increase of
pressure in flow line 16, and if the line is working properly,
pressure in line 16 will be in its intended operating range. Thus,
when valve 44 opens, the high-low pilot 10 will have closed, thus
maintaining pressure in line 18 and activating the actuator 20 with
pressure in line 18. The amount that the handle 50 is moved
downward establishes the length of the time-out period, for example
90 seconds maximum at 20.degree. C.
[0018] The time out valve 44 has a manually operated handle 50
which when pushed downward lifts a piston 52 and loads a spring 54.
When the piston 52 is moved upward, fluid above the piston 52 flows
through line 56 and piston O-ring valve 58 to the chamber 60 on the
other side of the piston 52. When the handle 50 is released,
pressure of the spring 54 forces the piston 52 downward and fluid
out of the chamber 60. Flow through valve 58 is blocked, and so the
fluid passes through flow restrictor 62 on line 64 back to the
other side of the piston 52. Line 64 may be a fitting on the valve
44. The flow restrictor 62 therefore provides a regulated time out
period that determines how long the time-out valve 44 remains
closed while pressure is built up in line 18.
[0019] If the flow line pressure does not come within the high and
low set points of the high-low pilot 10 before the end of the
time-out period, the high-low pilot 10 will shut down the ESD
system when the time-out period expires. If the flow line pressure
does come within the high and low set points of the high-low pilot
10 before the end of the time-out period, a circuit is supplied to
automatically end the time-out period and thus effectively reduce
the time-out period. This circuit includes a control line 70 that
senses pressure on the side of line 18 that is between the time-out
valve 44 and the valve actuator 20. The line 70 has a flow
restrictor 72 and delivers pressure to a port 74 of an arming valve
76. Arming valve 76 is provided on a line 78 that bypasses the
restrictor 62, so that when the arming valve 76 is armed, fluid in
reservoir 60 bleeds rapidly through line 78 to the other side of
the piston 52, thus ending the time-out period. Pressure build-up
sensed at port 74 of the arming valve 76 is regulated by bias
restrictor 72. The bias restrictor 72 allows pressure to build up
in line 18 upon operation of the hand pump 32, and allows the
pressure at port 74 to operate arming valve 76 when the pressure in
line 18 reaches the a low set point determined by the selection of
a spring 80 on the arming valve 76.
[0020] Although any flow restrictor may be used as the flow
restrictor 62 or 72 in the hydraulic control circuit disclosed
here, according to a further inventive aspect disclosed here, the
flow restrictor 62, 72 may be formed of plural loops of continuous
tubing 84A, 84B arranged in plural layers as shown in FIGS. 2A and
2B. The tubing 84A, 84B has a smaller inner diameter than the inner
diameter of the control line 70, 64. Preferably, the tubing 84A,
84B is spirally wound around a spool 86. The relative sizes of the
inner diameters of the tubing 84A, 84B and control line 70, 64 are
selected for a desired pressure differential across the restrictor
72, 62 respectively. The control line, as for example control line
64 in this case, may be a fitting on another part, for example a
valve, in which the case the inner diameter of the control line is
simply the inner diameter of the fitting. A restrictor of the type
shown here is preferred over conventional orifice discs with a very
small hole, since the small hole is subject to blockage, and the
small filter mesh used to prevent blockage is subject to blockage.
The elongated inner diameter of the plural loops of continuous
tubing is four to six times larger than an orifice disc diameter to
give the same amount of restriction to hydraulic oil flow. This
larger inner diameter accommodates the bulk of the contaminants in
the system, substantially reducing the requirement for cleaning,
and maintaining free flow through the filters and restrictors.
[0021] The sections in FIGS. 2A and 2B are characteristic of all
sections through the axis of the spool, except that the connections
appear as shown in only one section. For both restrictors 72, 62,
the tubing spools 86 are secured on a shaft 88 and protected by a
cylindrical housing 90 and top cap 92 held on bolt 94. At the
opposite end to top cap 92, the housing 90 is capped by a tubing
connector spool 96, as for example a swagelock fitting. In the case
of the bias restrictor 72 of FIG. 2A, the fittings thread into a
base plate 98 that has openings 100 for receiving the control line
70. In the case of the arming restrictor 62 of FIG. 2B, the
fittings thread directly into the valve 44 and themselves form the
control line 64. In an exemplary embodiment, the tubing 84A, 84B
had an inner diameter of 0.020 inches, and the control lines had a
diameter of 0.18 inches. The tubing 84A in an exemplary embodiment
is 88 inches long, while the tubing 84B is 15 inches long.
[0022] The pilot 10 is designed to bleed down an E.S.D. hydraulic
circuit when high or low pressures are sensed, such as in an
Oil/Gas production or pipeline facility. The high and low set
points are independently adjustable to meet predetermined levels,
in accordance with the desire of the operations personnel. The
pilot may be used for high only or low only or both high and low in
one unit. Several springs can be chosen to provide a broad range of
set points, in both high and low categories. Standard high and low
set points may range between 50 and 2000 PSI. Various conventional
fluids may be used as the hydraulic fluid, depending on the
temperature requirements, such as automatic transmission fluid and
aircraft hydraulic oil. Various conventional filter discs (not
shown here) are used within the hydraulic circuit disclosed here,
in proximity to the time-out valve 44, over-ride valve 30, relief
valve 26, hydraulic pump 32, arming valve 76, restrictor 72 and
high-low pilot 10 in conventional manner for protection of
hydraulic circuits and valves.
[0023] A person skilled in the art could make immaterial
modifications to the invention described in this patent document
without departing from the essence of the invention.
* * * * *