Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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. Description
HYDRAULIC PUMPING UNIT FOR WELLS
This application is a division of Canadian Serial
No. 397,289, filed March 1, 1982.
Technical Field
This inv~nkion relates generally to improved
pumping units, for use in oil wells, and more specifi-
cally to a hydraulic pumping unit.
As background, after dril1in~ a successful
oil well, a well casing of steel pipe is lowered into
the drilled well, in order to prevent the caving in
of the well and entry of unwanted material. Wet
cement is pumped into the casing of the well, and a
plug is placed on top of the cement. A stream ("head")
of water is then force pumped behind the plug, and
the plug forces the cement down into the hole, and up
the outside of $he casing. The plug goes to the
bottom of the casing, and together with the liquid
head, holds the cement outside until it hardens.
After the cement hardens, the casing is perforated at
the oil producing zone to allow oil to flow into the
casing. Next, production tubing is lowered into the
well. The tubing extends from the surface to below
the fluid level in the well. Oil to be recovered
will travel through the holes in the casing and up
the tubing to the surface.
Oil is brought up to the surface via a
variety of natural and man made forces (drives).
Several different kinds of underground pressure
(energy-drives) force oil out of the rock and into
the casing up to that level supported by the energy ;
drive and sometimes to the surface to create a "flowing
well". For e~ample, in water-drive fields, large
amounts of water under natural pressure exist under
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and at the edges of oil deposits. The water pushes
oil into the well and upward. In gas-cap-drive
fields, a cap of natural gas exists on top of the oil
deposits. The gas pushes down on the oil and forces
it up th~ well. In wells where there is not sufficient
underground pressure to force oil to the surface, it
is necessary to pump the oil to the surface. Thus,
for example, dissolved-gas-drive fields do not have
enough pressure to force the oil upward to the surface,
and most of the natural gas pr~sent is dissolved in
the oil. Even wells which contain sufficient under-
ground presure to force oil to the surface d~ring
the initial period of operation of the well will stop
flowin~ naturally after a period of time. After a
well stops flowing, pumps are installed to lift the
oil from underground. Most wells in the United
States are "pumpers".
In the conventional surface drive pumping
procedure, a subsurface or downhole pump is located
below the fluid level in the well, usually above the
producing zone. The pump is driven by a shaft,
normally in the form of a strin~ of "sucker rods"
extending from the pump through the production tubing
to the surface of the earth (slightly below the well
annulus at ~he surface), with the driving mechanism
being located at the surface. Thus, the reciprocating
shaft extends through the entire depth of the well to
the fluid level, and the oil being pumped from the
producing zone is in contact with both the sucker
rod, casing and tubing of the well during its (the
oil) travel from the producing zone to the surface.
- The surface driving mechanism which moves
(reciprocates) the sucker rod and moving part of the
downhole pump is commonly known as a "pumping unit".
There are many known types of pumping units, with the
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"walking beam" ("jack" type) units, technically known
as "crank balance pumping units", being the most
widely used in the field. A unit of this type operates
by attaching the sucker rod to one end of the tpivotal)
beam via known apparatus, a pivotal mounting or
fulcr~ being attached to the middle part of the
beam, and a driving unit being attached to the other
end of the keam. The driving unit consists of a
vertically positioned, shaft driven, counterbalanced
wheel crank which is attached through another member
directly to the walking beam. As the wheel crank
travels in a circular path, the walking beam is
lifted upwardly and then downwardly, and transmits an
upward and downward motion to the other end of the
beam as the beam is pivoted back and forth. This
results in the sucker rod and moving portion of the
downhole pump being reciprocated up and down.
Systems for reciprocating the sucker rod
which are based upon hydraulics have also been devel
oped. These systems involve feeding a hydraulic
fluid to a cylinder, and raising a piston within the
cylinder, with the piston rod being connected indirect-
ly to the sucker rod. The flow of the hydraulic
fluid within the cylinder is used to control the
reciprocating motion of the sucker rod. In certain
cases, the cylinder and piston are located below
ground, in the downhole, with hydraulic fluid being
flowed to the cylinder from above ground, with the
operation also being controlled from above ground.
Backyround Art
When multiple pistons and multiple cylinders
have been used in pumping units, the pistons have
been connected together via a fixed piston rod, such
that all of the pistons moved together as a unit.
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This was done so that the force applied could be
increased, since the area of the faces of all of the
pistons would contribute to the force being applied.
Further, the prior art employed complex systems, when
dealing with hydraulics to reciprocate the sucker
rod. Representative patents for the above would be
U. S. Patent 2,245,501 to Richardson, U. S. Patent
3,540,814 to Roeder, U. S. Patent 3,58~,238 to Devine,
and U. S. Patent 2,665,551 to Chenault. Further, a
HEP system (hydraulics, electronics, pneumatics)
using one lift cylinder, and a counterbalance cylinder,
has been developed as an above-ground pumping unit.
In other instances, hydraulic assists are utilized
with a hydraulic cylinder and piston employed to aid
in lifting the sucker rod end of the walking beam.
However, the prior art has not developed a
hydraulic pumping unit which is simple to install and
use, easy to re~ulate and main~ain, easily transport-
able to any location, efficient, and easily matched
to the demands of any wellO
Disclosure of Invention
It is an object of the present invention to
provide an improved hydraulic pumping unit.
It is a further object of the present
invention to provide a pumping unit which is reliable,
simple to use, easy to maintain, easily transported
to any location, conventional as respects its instal-
lation and its pumping motion, efficient, and easily
matched to the demands of many wells.
In order to attain these and other objectives
(which will become apparent from the specification),
the invention provides a pumping unit as follows.
A plurality of cylinders are arranged
substantia11y in a vertical straight line, such that
the piston rod of each cylinder is connected to the
end of the hydraulic cylinder which is next in the
straight line. The line of hydraulic cylinders can
be arranged such that the piston rods extend upwardly,
or such that they extend downwardly. If the piston
rods extend upwardly, the topmost rod is connected to
hang from a gravity centering member of a frame which
suspends the entire cylinder assembly from the frame
positioned and centered over the well. If the piston
rods extend downwardly in the assembly, the -topmost
cylinder is connected to the gravity centering member,
which is connected to the frame. The gravity centering
connection member is fixed to and suspended from the
top of the frame, such that the assembly can swing
freely, centered and alligned by the force of gravity.
While it is sufficient to employ only one gravity
centering member which is suspended from the frame
with the piston rod-cylinder co~nections being rigid,
the preferred embodiment involves employing a gravity
centering or hanging member between each cylinder and
each piston rod, such that the gravity centering
member is connected at one end to the piston rod
extending from one cylinder, and at the other end to
the next cylinder.
The cylinder assembly is connected to the
sucker rods by way of the polished rod (which moves
up and down through a stuffing box at the well annulus);
the sucker rods, in turn, to the moving part of the
downhole pump, which pump urges oil toward the surface.
The feeding of hydraulic fluid to the cylinders
provides movement of the cylinders, the polished rod,
-~the sucker rod, and the moving portion of the downhole
pump, such that each of these members reciprocates up
and down, and such that oil is brought toward the
surface through the tubing.
Although reference is made throughout the
specificatlon to oil, the present invention would
obviously apply to any other fluid which can be
pu~ped from a downhole via a reciprocating motion.
While hydraulic fluid, via the extension
and contraction of the suspended cylinders, can be
used to both raise and lower the sucker rod and down
hole pump system, th~ force of gravity can also be
used in lowering the sucker rod and down hole pump
sy~tem, a~ter it has been raised via the hydraulic
fluid. Walking beam type pumping unit~ store part of
the gravitational energy generated on downstroke and
use it on the upstroke, via counter balance weights
attached via "pittman arms" to the "wheel crank". In
a hydraulic pumping unit, compressed gas can be used,
in order to store the energy dissipated by either the
force of gravity or use of hydraulic fluid on down-
stroke. Even further, a partial vacuum can also be
used to store energy. Therefore, another embodiment
of the present invention is provided, whereby the
~ylinder-piston assembly of each piston ca~ be
modified, such that excess hydraulic energy and
gravitational energy are stored in each stroke. This
is accomplished for example by locating a plurality
of energy storing pistons (or one if desired) at the
side of, or attached to, each of the working pistons.
As the sucker rod assembly is moved downwardly through
the well, the side pistons store energy in the orm
of gas being compressed in one of the chambers of the
side cylinders, while at the same time, a partial
vacuum is being increa~ed due to the movement of the
pistons relative to the cylinder~.
In accordance with the principal object, the
invention contemplates a hydraulic pumping unit, capable OL
driving a downhole pump in a well, such that well fluid
will be brought to the surface of the well. The unit
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comprises a frame, and a plurality of hydraulic cylinders, with
each cylinder comprising a cylinder housing, a piston slid-
ably mounted within the cylinder housing, and being capable
of moving up and down within the cylinder housing, wherein
the piston has an upper and lower face. A piston rod is
fixed at one end to one of the faces of the piston, with
the other end of the piston rod protruding from one of the
ends of the cylinder housing. A port means is provided
capable of permitting the flow of fluid into and out of the
cylinder housing. An intermediate connection means connects
the piston rod of one cylinder to the end of another cylinder
located immediately adjacent the one cylinder and is positioned
between the plurality of cylinders such that all of the
cylinders are linearly connected and a multi-cylinder system
is provided. An upper connecting meanssu~pe~s and gavity
centers the multi-cylinder system and is connected to a
point at the top of the frame to either the piston rod or
the cylinder housing of the top hydraulic cylinder of the
multi-cylinder system. A lower connecting means is connected
at one end to the end of the lowest cylinder of the multi-
cylinder system, and the other end of the lower connecting
means is connectable to a rod located below the lowest
cylinder, such that the rod can be reciprocated up and down
by expansion and contraction of the multi-cylinder system. The
upper portion of each cylinder housing together with the
upper face of each piston located within each cylinder housing
defines an upper cavity for the flow of fluid, such ~hat
each piston is urged downwardly relative to the cylinder
housing in which it is located when fluid is fed into the
upper cavity. The lower portion of each cylinder housing
together with the lower face of each piston located within
each cylinder housing defines a lower cavity, such that each
piston is urged upwardly relative to the cylinder housing
in which it is located when fluid is fed into the lower
cavity.
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In a further embodiment, there is provided a
hydraulic purnping system, capable of driving a downhole
pump in a well, such that well fluid will be brought to
the surface of the well. The system comprises a hydraulic
cylinder, means for supporting the hydraulic cylinder,
and means for feeding hydraulic fluid to the cylinder, such
that the cy~inder will be reciprocated up and down. A
piston and a piston rod fixed to the piston is provided,
with the piston being slidably mounted within the hydraulic
cylinder for upward and downward movement within the hydraulic
cylinder. A means connects the piston rod to another rod.
A heat exchanger is provided capable of thermally contacting
the hydraulic fluid with effluent fluid from a well, and a
means feeds effluent from a well to the heat exchanger. A
means feeds the hydraulic fluid from the hydraulic cylinder
to the heat exchanger, and a means returns the hydraulic
fluid from the heat exchanger to the means for feeding hydraulic
fluid to the cylinder.
Still furthe-, the invention provides for a cylinder
assembly which comprises a hydraulic cylinder houslng, at
least one pneumatic cylinder housing, a hydraulic cylinder
piston slidably mounted for reciprocal motion within the
hydraulic cylinder housing, with a piston rod being fixed
to one face of the hydraulic cylinder piston and protru~ing
from the hydraulic cylinder housing. A pneumatic cylinder
piston is provided for the pneumatic cylinder housing, with
the pneumatic cylinder piston being slidably mounted within
each pneumatic cylinder housing, and with a piston rod being
fixed to one face of each pneumatic cylinder piston. A
means secures the pneumatic cylinder to the hydraulic cylinder,
such that the pneumatic cylinder is secured to the hydraulic
cylinder in a side-to-slde relationship. A means connects
the pneumatic and hydraulic cylinder piston rods to~ether,
such that the pneumatic and the hydraulic cylinder piston
rods move together. A port means is located in the hydraulic
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cy1inder housing and is capable of permitting the entrance
and exit of hydraulic fluid to cavities in the hydraulic
cylinder, to force the hydraulic cylinder piston to slide
within the hydraulic cylinder housing. A means defines a
plurality of cavities in the pneumatic cylinder housing,
wherein one cavity of the pneumatic cylinder is capable of
retaining a compressible fluid such that it is compressed
upon movement of the piston rods in one direction, and the
other cavity of the pneumatic cylinder is capable of retaining
a partial vacuum in the cavity, such that the degree of
vacuum is increased upon movement of the piston rods in the
one direction.
The invention also encompasses the novel method of
pumping fluid from a wèll having a downhole wherein the well
has a downhole pump attached to a rod system and extending from
the pump to the surface of the well. The method comprises
positioning a frame over the annulus of the well and connecting
a multi-¢ylinder system to a frame connection point at the top
of the frame, such that the multi-cylinder system is gravity
centered and suspended from the fra~e, wherein the multi-
cylinder system comprises a plurality of cylinders with
each cylinder comprising a cylinder housing, a piston slidably
mounted within the cylinder housing, and being capable of
moving up and down within the cylinder housing, and wherein
the piston has an upper and lower face. A piston rod is fixed
; at one end to one of the faces of the piston, with the other
end of the piston rod protruding from one of the ends of the
cylinder housing. A port means is provided capable of permitting
the flow of fluid into and out of the cylinder housing. One or
more intermediate connection means connects the piston rod or
the cylinder housing end of each cylinder housing to the piston
rod or cylinder housing end of the next cylinder in the multi-
cylinder system. The intermediate connection means is connected
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between the plurality of cylinders. The method also
comprises connecting the piston rod of the lowest cylinder
of the mu1ti-cylinder system to the upper end of the rod
system and feeding hydraulic fluid to the cylinders of the
multi-cylinder system, such that the rod system and the
moving part of the downhole pump are reciprocated upwardly
and downwardly.
ln its broadest aspect, the invention contemplates
a pumping unit for reciprocating the rod of a downhole pump
for pumping fluid from a well which comprises a frame, a
plurality of pressure responsive expansion mem~bers coupled
together in sequence, with each of the expansion members
being capable of expanding and contracting to produce a
linear reciprocating movement, and gravity centering means
connected to the frame and to a first one of the sequence of
expansion members for suspending the sequence of expansion
members to provide gravity centered alignment thereof over
the well. A control means is coupled to at least one of
the expansion members for selectiuely providing pressurized
fluid thereto in order to selectiuely expand or contract the
expansion member. A last one of the sequence of expansion
members is connected to the rod of the downhole pump, whereby
the total amount of reciprocating mo~ement imparted to the
pump rod is equal to the sum of the individual reciprocating
linear movements of each of the reciprocating members being
selectively expanded or contracted.
The accomplishments and advantages of the
present in~ention will be more fully understood from
the drawings, specifications, and description of the
advantages of the present invention which follow.
Brief Descripkion o Drawin~_
Figure 1 is a partly sectional and partly
elevational view of a preferred embodiment a multi-
cylinder system in accordance with the invention,
suspended from a frame which is bolted to the well
casing head.
Figure 2 is a partly sectional and partly
elevational schematic representation of the multi- ;
cylinder system of the invention, suspended from a
frame which is independently supported on an I-beam
platform.
Figure 3 is a sectional lengthwise view of
one embodiment of a working cylinder according to the
present invention, having two pneumatic energy storage
cylinders located on either side of the working
hydraulic cylinder.
Figure 4 is a diagrammatic representation
of the sequential action of the multi-cylinder system.
Figure 5 is a partial].y sectioned view of
another embodiment of a working cylinder in accordance
; with the present inv~ntion, and appears with Figs. 1 and 6.
Figure 6 is a partial].y sectioned view of
another embodiment of a working cylinder according to
the invention, and appears with Figures 1 and 5.
Best Mode for Carr~in~ Out the Invention
In describing the preferred embodiments of
the present invention, which are illustrated in the
drawings, specific terminology will be resorted to
for the sake of clarity. However, the invention is
not intended to be limited to the specific terms so
sel~cted, and it is to be understood that each specific
term includes all technical equivalents which operate
in a similar manner, to accomplish a similar purpose.
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With reference to Figures 1 and 2, the
preferred embodiment with respect to the hanging
multi-cylinder pumping unit according to the present
invention will now be described. The oil is urged
upwardly toward the surface of the well by way of a
subsurface or downhole pump 26 which conventionally
includes a standing valve 1 and a traveling valve 2.
The traveling valve 2 is connected to the bottom of
the sucker rod assembly (which can include a plurality
of rods connected together) with the sucker rod being
shown in the drawings as 3. As is known with respect
to c~nventional subsurface oil well pumps, the travel-
ing valve is opened by the downstroke of the sucker
rod, such that oil located in the lower chamber of
the pump flows into the upper chamber of the pump
which has moved downwardly. During the upstroke of
the sucker rod, the travelling valve is closed and
- the oil within the upper chamber of the pump is moved
upwardly, thus lifting all the oil in the tubing up
toward the surface of the well. At the same time,
the stanaing val~e is opened, and the partial vacuum
which is created by the upper chamber of the pump
moving upwardly results in oil flowing into the lower
chamber of the pump, since the standing valve has
been opened. This explanation of the operation of a
subsurface oil well pump is merely by way of example,
and is not considered to be a part of the invention.
A conYentional subsurface pump for pumping oil upward-
ly through tubing is shown in U.S. Patent 2,530,673
to Zinsæer. There are many other types o subsurface
pumps. It is to be understood that any subsurface
oil well pump which can be operated by a reciprocat
ing motion within the well casing can be used for the
purposes of the present invention.
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The sucker rod 3 is an assembly of a string
of sucker rods extending from the pump all the way to
the connection with the polished rod, or might simply
be one cable or rod which extends from the pump to
the polished rod. The lower end o~ the polished rod
is indicated at 6, and the upper end is indicated at
7. The well casing is indicated at 4, and the tubing
through which the oil flows upwardly is indicated at
5. The tubing is suspended from tubing ring 9/ and
the well casing head is indicated at 8.
The oil is pumped upwardly through the
tubing and into a tee 10, which directs the oil to
piping and tank batteries, which are not shown in the
present drawings. Stuffing box 11 prevents the oil
; 15 from rising upwardly around the polished rod, rather
than exiting through the side pipe of the tee. The
stuffing box ~packing box) contains a non-rigid
material such as rubber, and is akin to the stuffing
box on a boat, through which box the shaft passes
from the hull to the water. As indicated above, the
sucker rod is connected at its lower end to the
moving part of the subsurface pump. The upper end of
the sucker rod is connected to the polished rod,
which is in turn connected to the polished rod carrier
bar 12, by way of the rod clamp 14. The carrier bar
is connected to the lowest cylinder, of the multiple
cylinder assembly shown in Figures 1 and 2 via wire-
line 13, which can he a cable (made for example of
wire) or can be a rod.
The multi-cylinder system includes a plurality
of cylinders 25, with the number four (which is shown
in the drawing) not being critical to the present
invention. The cylinders 25 are held together by tie
rods 20, and have pistons 21 and piston rods 22. The
structure of a working cylinder 25 usable with the
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present invention can be understood ~y reference to
the working cylinder shown in Figure 3, which will be
discussed below. However, the structure of the
working cylinder shown in Figure 3 is not critical to
the invention, and any expansion member which can be
expanded and contracted using hydraulic fluid and
will perform the purposes of the present invention
can be used herein. For example, a cylinder might
have two pistons with each being connected to a
piston rod protruding out of each end of the cylinder,
where fluid is fed between the pistons to move the
rods outwardly and fluid is fed to the upper and
lower cavities of the cylinder to move the pistons
and rods together. It should also be noted that the
section shown for the cylinder of Figure 3 can repre-
sent a cylinder which is circular in cross section,
or can represent a cylinder which is square in cross
; section, or any other geometric shape, for which the
cylinder can surround the piston. Of course, the
geometric shape of the piston will conform to that of
the cylinder housing. Thus, for example, a hexagonal
piston might be located within a hexagonal shaped
cylinder having a hexagonal cylinder housing.
~ However, a circular cylinder and piston are preferred.
; 25 Hydraulic fluid can be 10wed from sources
(not shown in the drawings) through hydraulic fluid
lines 23 and 24 to either the upper or lower chambers
of each cylinder. When fluid is flowed inwardly
through hydraulic line 23, the cylinder moves upwardly
relative to the piston 21. ~hen fluid is flowedinwardly through hydraulic line 24, the cylinder is
moved downwardly with respect to piston 21. As can
be understood, the movement of each cylinder in an
upward direction will contribute to the movement of
the polished rod, sucker rod system, and moving
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portion of the pump in an upward direction. Movement
of a cylinder in a downward direction will contribute
to moving the above-mentivned elements in a downward
direction.
Although not shown in the present drawings,
any conventional control means can be used to control
when fluid is provided to either of lines 23 or 24,
how much fluid is flowed per unit time, and which of
the cylinders will receive fluid. The control means
can be made responsive to downhole conditions and to
failure of one of the cylinders by any conventional
sensing means with feedback to the control means.
Connecting and suspending members 15 will
connect piston rods 22 and cylinders 25, and will
also connect the multi-cylinder system to frame 16.
Connecting and suspending members 15 can be wireline
or rods or anything that will support the weight of
the cylinders, polished rod, sucker rod assembly, and
oil being pumped. The suspension of the connecting
and suspending members 15 is such that the connection
permits movement in any direction. Thus, for example,
a ball-in-socket connection might be used, or a
plurality of hinges might be arranged such that the
cylinder system can completely center itself in line
with the gravitational force. While it is critical
that a gravity centering (connecting and suspending)
member 15 be hung from the frame 16 in order to
permit centering of the cylinder system, it is prefer-
able to also employ a gravity centering member 15
between each of the cylinders of the cylinder assembly,
such that a member is connected to the piston rods of
~each cylinder, and the end of the next cylinder in
line.
While Figures 1 and 2 show the positioning
:~. 35 of the multi-cylinder system such that the piston
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rods extend upwardly, the invention can equally be
practiced in a manner, as shown in Figure 5, such
that the ends of the cylinders 525 are suspended from
above, and the rod 522 of piston 521 extends downwardly
to be connected with the next lower cylinder via
member 515, with hydraulic lines 523, 524.
Further, as shown in Figure 6, the cylinders
can be aligned such that the cylinder ends of two
adjacent cylinders 625, 625A are connected at 690,
while the piston rods of two other adjacent cylinders
are connected to rods 622, 622A via the connection
member 615. Thus, although it is not the preferred
embodiment of the present invention, the cylinders of
the multi cylinder system can be aligned such that
the piston rod of one cylinder is connected to the
piston rod of the cylinder immediately above it, and
such that the end of the cylinder is connected to the
end of the cylinder immediately below it. Thus, sets
of cylinders facing each other (as two piston rods
and as two cylinder ends) can be provided within the
multi-cylinder system. Expansion and contraction of
stroke would be accomplished by this embodiment of
the invention in the same manner as described above
via hydraulic lines 623, 624, 623A and 624B, this
face to face association of cylinders or rods forms a
part of the present i~vention. In the case of a
cylinder having two pistons as in the example mention-
ed above, all connections will be piston rod to
piston rod.
The vertically aligned multi-cylinder
system may be located above the ground and supported
by frame work either bolted directly to the casing
head as shown in Figure 1 or independently supported
upon a conventional foundation of gravel, wooden or
steel beams, concrete, or a combination therof.
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Figure 2 shows the use of steel beams, with rPference
to frame 17 which is indPpendently supported on an
I-beam platform 18. It is possible to locate the
fluid cylinders 25 just below the ground level 19,
within the well casing, while it is also possible to
locate the fluid cylinders 25 downhole nearer to the
level of the fluid to be pumped. The structuxal
connecting members 15 between the multi-cylinder
system and the framework, and betw~en the piston rod
of one cylinder and the casing or cap of the nsxt
cylinder can be either rigid or flexible as long as
the ultimate connections involved permit gravity
centering.
The gravity centering of the present inven-
tion is obtained by hanging the cylinder system fromabove. Gravity and the weight of the sucker rod and
fluid column combine to naturally maintain alignment
of the system. Because the multi-cylinder system is
centered over the well, the frame may easily be
aligned at set-up by suspending a plumb bob from the
suspension point of the frame to the center of the
well head.
The piston of each cylinder is connected to
the next cylinder, so that individual piston displace-
ments are additive to give a total system displacement,and a desired stroke length for pumping the oil. As
pointed out above, the pistons may protrude from the
cylinders toward the well or in the opposite direction
away from it. In either case, extension of the
pistons will produce linear movement toward the well
and retraction of the pistons will produce a reciprocal
linear movement away from the well. The pistons can
all be extended in the same direction at the same
time, in order to provide maximum stroke length for
the system, or some pistons might be moving upwardly
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while others are moving downwardly, or a piston might
not be moved at all while the other pistons are being
moved. The desirability and instances for regulation
of piston movement will be discussed in more detail
below.
Although the drawings show the cylinders o~
the present invention to be double acting with upper
and lower hydraulic chambers, the fluid cylinders may
be single acting, with one hydraulic chamber, and one
chamber which is vented to the atmosphere. In such a
case, the hydraulic chamber will be used to lift the
sucker rod assembly, while gravity will be used to
lower it. The cylinders also might have one hydraulic
chamber and one pneumatic or vacuum chamber acting as
a counterbalance and~or booster. In the use of
hydraulic chambers for the cylinders, a benefit is
derived from conventional hydraulic/pneumatic accumula-
tors within the fluid circuit to act as counterbalances
to the rod and fluid weight, and to receive and store
for use on upstroke excess pump output and energy
generated during the downstroke. A system for storing
excess pump output and energy generated during down-
stroke is shown in U.S. Patent 2,665,551 to Chenault.
Further, and as a preferred embodiment of the present
invention, a pneumatic cylinder or pneumatic cylinders
positioned laterally to and acting together with the
working hydraulic cylinders of the cylinder system can
be used as an alternative to the accumulators within
the fluid circuit as discussed. The use of pneumatic
cylinders positioned laterally to the working hydraulic
cylinder and acting with it can be seen by reference
to Figure 3.
Figure 3 shows two pneumatic cylinders 36
which are positioned on either side of a central
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working hydraulic cylinder 38. Although two pneumatic
cylinders are shown positioned laterally beside a
given hydraulic cylinder in Figure 3,any number of
pneumatic cylinders could be positioned as such, and
still be within the present invention. The pneumatic
cylinders 36 operate in tandem with the working
hydraulic cylinders 38 with which they are associated.
In the present case, a triplet of cylinders is shown,
and this triplet may be repeated as often as wished,
to make up a vertically aligned system. As can be
seen, the vertical movement of the pneumatic cylinders
is necessarily identical to the movement of the
working hydraulic cylinders with which they are
associated. In Figure 3, it can be seen that the
piston rods 31 of one triplet of cylinders can be
conveniently connected to the next triplet of
cylinders, by screwing the piston rods into the end
plate 34 of the next triplet of cylinders.
In operation of the triplet, the upstroke
in which the sucker rod assembly is raised will first
be described. Fluid is forced into cavity 46 forcing
the piston 39 relatively downward within cylinder 38
and cylinder housing 50, thereby contracting the
~ assembly. As this occurs, the counterbalance pistons
- 25 37 assist the action by using energy from the gas in
cavities 44 which gas was compressed on the previous
downstroke and also using the vacuum created in
cavities 40 which vacuum was also created on the
downstroke.
On the downstroke, fluid is fed to cavity
42 (or if desired, gravity may simply be reli~d
; upon), and pistons 39 and 37 move upwardly relative
to the cylinders of the triplet. The upward movement
of counterbalance pistons 37 serves to compress the
gas in cavities 44, and to enlarge the partial vacuum
"
' ', ' '. :
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- 16 -
in cavities 40, and this stores gravitational and
excess hydraulic enexgy for use in the next upstroke.
With respect to the assembly of the triplet~
it should be noted that the cylinders are held in
place by way of end plates 34, 34' which are secured
by tie rods 35. The tie rods are inserted within
countersunk bores in the end plates, and are tightened
by screwing tie rod nuts 33 within the countersunk
bores. Rod seals 49 and xod bearings 48 are also
provided with respect to the piston rods for each of
the cylinders, as shown in Figure 3, and fluid ports
41, 43, 45, and 47 are provided in and through the
cylinder housings 5U and 51 for introducing hydraulic
fluid into respective cavities 40, 42, 44, and 46 as
necessary. The conventional valves which are not
shown will obviously regulate whether fluid is or is
not introduced through the fluid ports. The valves
can be constructed such that they simply permit the
entry of fluid at a certain flow rate or prohibit the
flow of fluid or the valves can also be constructed
to regulate the rate and direction of fluid flow as
time progresses (although this is less desirable,
æince complicated valve mechanisms are needed).
As pointed out above, the pneumatic cylinders
of the invention may be mounted as shown (with the
piston rods 31 facing up), or the cylinders can be
mounted with the piston rods acing down if desired.
Further, any or all of the (working) cylinders shown
in Figures 1 and 2 can be provided with laterally
positioned pneumatic cylinders. Where the connection
between the piston rods and the cylinder is to be by
way of co~necting and suspending member 15, the
assembly of Figure 3 would be modified by screwing
piston rods 32 into one side of a separate plate
member, and then attaching suspending member 15 to
' , ,
.
the other side of that plate member and to the end of
the next cylinder.
With respect to Figure 3, the end plates
can be rectangular, square, or circular (ox any other
shape), depending upon the desire of the artisan.
Further, the cylinders and pistons can be square,
rectangular, or circular (or any other shape), again
depending upon the desire of the artisan. Thus, it
is within the present invention that pistons 37 can
simply be two square or round pistons which are
located on either side of square or round piston 39
with the cylinders also b~ing either square or round.
As a further embodiment of the present invention, two
further pistons 37 can be located in front of and in
back of piston 39 together with their respective
cylinders, where a sguaxe end plate 34 is used to
accommodate the entire assembly. Further, piston 37
can be an ar~ular member extending around piston 39,
with 51 repxesenting an ar~ular housing. Further,
the mechanism could also work well with cylinders
sliding within each other (compound cylinder with one
cylinder acting as the piston).
As pointed out above, the embodiment of
Figure 3 is merely a preferred embodiment, and is not
required for the present invention as can be seen by
Figures 1 and 2 which do not have such a counterbal-
ancing cylinder assembly.
With respect to the hydraulic power required
to operate the multi-cylinder system of the invention,
such may be supplied by any conven~ional hydraulic
prime mover, powered by gas, liquid fuel, or electricity.
Thus, for example, a direct drive electric motor, a
belt driven oil field type gas engine, or a diesel
powered engine might be used for the prime mover. In
order to transmit power from the prime mover to the
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.
- 18
pistons of the cylinders, a conventional motivating
pump such as a reversible variable displacement pump
or a centrifugal pump can be used. Any motivating
means which can feed fluid to the cylinder cavities
under sufficient pressure and thereafter permit
withdrawal (discharge) of the fluid from the cavities
can be used for the present invention. Any other
conventional hydraulic circuitry such as the hydraulic-
pneumatic accumulators can be used where appropriate
in order to facilitate operation of the hydraulics in
the present invention. The power source and controls
for the hydraulic flow into the cylinders of the
invention can be located at a source either distant
or near the well head, again as desired.
The hydraulic lines 23 and 24 can be con-
nected to a single hydraulic feed system and power
source; however, there may be applications where each
cylinder would have its own feed circuitry and power
source. In certain instances, there may be provided
one power source to run most of the cylinders, while
another power source or sources run the remaining
cylinders. For example, if the number of strokes per
minute of an operating pumping unit must be increased
beyond the capacity of the prime mover, and the
stroke length is to remain the same, an additional
; power source can be added to the hydraulic system in
order to power one or more of the cylinders, without
having to change the stroke le~gth or number of
hydraulic cylinders.
In using the multi-cylinder system of the
invention, individual cylinders may be added to or
subtracted from the system. This facilitates adjust-
ment for changing stroke length demands over time as
is now common in the evolution of producing oil and
gas wells. As with conventional single hydraulic
~L7~9~
- 19 - ~
cylinders, stroke length can also be altered by
shortening the extension/contraction cycle, and
stroke time can be altered simply by changing the
volume per unit of time of the fluid entering (and
leaving) the cylinder chambers. Stroke lengths can
most easily be changed by altering the phasing of the
individual cylinders as described below. Because
matching of well demands and pumping units is a
multi-faceted problem and often involves rough esti-
mates, the innate variability of the multi-cylinder
system of the in~ention provides a decided advantage
both in terms of time and cost. In the system of the
invention, when one cylinder becomes frozen or other-
wise inoperable, pumping is continued by modifying
either the phasing of the other cylinders or possibly
the amount of fluid fed to the other cylinders tal-
though modifying the amount of fluid fed is not
preferable, since this re~uires a more complicated
variable valving system).
The aspect of easily or automatically
changing or altering the stroke period or length in
response to changes in downhole conditions would be
very advantageous to the following pumping situations:
1. Bringing on new wells which tend to be
unstable or erratic during the initial production
period.
2. Surging wells in which fluid flow and
pressure may substantially change several times
a day.
3. Any well which requires close observa-
tion and numerous changes in pumping unit settings.
- An important aspect of the invention which
can be obtained via the multi-cylinder assembly of
the present invention can be understood as follows.
Historically, one of the major problems in reciprocal
- 20 -
pumping unit design has been meeting the increased
stresses which are imposed during the reverses in
reciprocal action, particularly when changing from
downstroke to up~troke. Reverses should proceed at a
more gradual pace than the straight upstrokes and
downstrokes; however, this has been difficult to
achieve. In a distinct advantage of the aligned
multi-cylinder system, according to the invention,
the reciprocating actions of the cylinders may be
phased such that the reverses in direction of motion
of the individual cylinders proceed in a sequential
; order. The sum of the sequential movements of the
individual cylinders thus produces a smoother more
gradual transition than is possible, with a single
; 15 hydxaulic cylinder, without use of special and
complicated valving. This can be illustrated by the
following example of a five cylinder system, as
exemplified in Figure 4. In the graph of stroke
velocity over time as shown in Figure 4, the plus
sign represents the upstroke portion, the minus sign
the downstroke portion, and zero represents stroke
termination of the pumping unit. With respect to the
individual cylinders 401-405 shown in the schematic
diagram of Figure 4, each cylinder is represented as
being in the states of expanding, contracting, neutral
open, and neutral closed by the symbols e', c', no',
and nc'. The positions a, b, c, d, and e of the
cylinders correspond to the movement of the pumping
unit through its complete upstroke and downstroke.
In a five cylinder system, the termination,
transition or reverse point for the system as a whole
is reached when two cylinders 401, 402 have just
passed their individual transitions (full extension)
and two cylinders 404, 405 are nearly approaching
their transition points (full extension), while
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- 21 -
center cylinder 403 is at a neutral open position.
As the overall contraction of the stroke is begun,
three cylinders 401, 402 and 403 are actually begin-
ning the contraction, and therefore the contraction
in stroke begins gradually, since cylinder 403 has
just passed its neutral open position, while cylinders
404, 405 are still expanding. As cylinders 403, 404,
405 begin their contraction, the velocity of contrac-
tion is increased to the steady state point b for the
upstroke. Upon completion of the upstroke at the
point c where the desired stroke length s is being
attained, cylinders 401, 402 are still moving to
complete the increase in stroke length, cylinders
404, 405 are contributing to stroke decrease, and
center cylinder 403 is at a neutral closed position.
Thus, the extension to the desired stroke lengths is
completed with a gradual termination, since all five
pistons are not moving to complete the stroke, but
rather one at a time. Completion of the downstroke
through points _ and e is similarly carried out.
Therefore, it can be seen that the present invention
will provide a dampened reciprocating action for the
stroke by properly controlling the phase of the
pistons of the cylinder-assembly.
This concept of some cylinders reversing
direction as other cylinders are finishing their
travel in one direction provides, in sum, a smooth
transition between downstroke and upstroke and between
upstroke and downstroke. As a piston within a hydrau~
lic cylinder finishes one direction of stroke, there
is a lag period where the piston does not move, while
; the control mechanism changes conditions (for example,
flow valves are changed from opened to closed), such
that the piston is now ready for movement in the
reverse direction. During this period of time, no
: .
movement (of the individual cylinder) in either
direction is obtained. Further, since the piston is
stationary for a brief period of time, movement is
not smooth. This has jerking or jarring effect,
imposing stress on the sucker rod assembly and the
subsurface pump itself. By use of the presently
described procedure with sequential reversing pistons,
this problem is mitigated. While the leading piston
is stationary, due to the above-described lag, the
trailing pistons are still increasing the stroke.
Ater the trailing pistons have reached their full
extension, the pistons all begin to contract. Thus,
the system will go from gradual termination of down-
stroke velocity to gradually increasing velocity of
upstroke, until a steady state velocity of contraction
(upstroke) is obtained. This procedure will provide
rapid attainment of steady state stroke velocity, yet
permit both a gradual change from downstroke to
upstroke. It will in the same manner, give a gradual
and smooth change from upstroke to downstroke.
A less smooth but dampened reciprocating
action can also be provided by terminating the stroke
of two cylinders slightly out of phase to the stroke
termination of the next two cylinders. It can be
seen that the greater the number of cylinders in
seguence, the smoother the termination
Sequential action is accomplished by regu-
lating the timing for which fluid will enter and
leave the cylinders, by use of sequential valves. An
electrical and/or mechanical system can be used to
control all of this.
; It should be noted that various hydraulic
control mechanisms are available as components which
may be combined to enable automatic sequential opera-
tion of the present multi-cylinder system. A series
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- 23 -
of main fiveway control valves, one for each cylinder,
may in turn be pilot controlled by a similar number
of secondary seguence valves so that transition from
downstroke to upstroke (and visa versa) is carried
out sequentially. Further, variable control of the
input to the series of secondary sequence valves will
easily allow variation of the duration of the total
system transition time, thus producing the desired
degree of stroke damping in reciprocal motion.
Though not the preferred embodiment, it would obvious-
ly be possible to operate the multiple cylinders
simultaneously or with one designated cylinder leading
or lagging the others and acting as a motion damper.
It is important to be able to regulate the
speed at which stroke termination is accomplished, in
accordance with the depth of the hole involved, the
fluid level in the hole, the fluid flow rate, and
other downhole conditions. The closer the action of
the cylinders, the more rapid will be the stroke
termination and the longer the stroke. Conversely,
the further away from each other the action of the
individual cylinders, the more gradual the termination
and the shorter the stroke (and the greater the
overall power or lift). If half the cylinders are in
opposite phase to the other half, there will be no
overall motion. Thus, it can be seen that through
phasing of the individual cylinders in respect to
each other, overall stxoke length, termination time
and lift power can be altered to suit the desired
condition. The action of the cylinders can be regu-
lated via the present invention to accomplish the
- stroke action desired, without the use of special
valves, in addition to the hydraulic valves which
permit flow into the cylinders. The individual
~ 35 cylinder's strokes can be lengthened ~within the
.~ , . .
- 24 -
range of the individual cylinder's fluid capacity) by
lengthening the hydraulic fluid injection cycle, and
shortened by the converse. The simplicity of control
via the present invention is quite clear, and chances
of malfunction are reduced, since the timing of the
hydraulic valve action is the only thing which need
be regulated. Thus, it can be seen that the rate of
fluid flow into the cylinders need not be changed, as
the stroke progresses upwardly and downwardly; since
the phasing of the cylinders will accomplish the same
result. All that is required for the valves of the
present invention, is that they be able to permit a
steady but timed flow of hydraulic fluid into and
from the cylinder.
In using the multi-cylinder system of the
present invention, the pumping unit's frame or derrick,
whether attached to the well head (annulus~ or ground
supported, is centered with a plumb-bob (gravity)
hung from the point-of-attachment of the top most
cylinder (or piston rod). Once the frame is centered
and secured over the polished rod, the hydraulic
cylinder as~embly is hung from that point-of-attachment.
Gravity then maintains the alignment and plumb of the
hydraulic cylinder assembly. The lower most cylinder
(or piston rod) is then attached to the polished rod.
The stuffing box is then screwed onto the top of the
tee such that oil flows through the side pipe of the
tee, and the system is ready for reciprocal pumping
of the oil out of the well.
Accordin~ to another facet of the in~ention,
after the hydraulic cylinder assembly has been gravity
centered, a member can be rigidly fixed to the frame
and further rigidly fixed to the top cylinder. The
member can be fixed, such that the cylinder assembly
can no longer sway in any direction, but the cylinder
~7~
- 25 -
assembly remains gravity centered. This member
(which can be for example a suitable housing, brace
or bracket, slide or track) can remain in position,
until the pumping unit is finally removed and moved
to another well location. The use of a member which
rigidly fixes the gravity centered multi-cylinder
system to the frame (after gravity centering) is
considered an advantageous modification of the present
invention, since the rigidity of the multi~cylinder
system may be used more effectively to increase
stroke speed in the downward direction, though this
is not the preferred embodiment. Where gravity
centering members are used between adjacent cylinders,
bracket or brace, slide or track or guide like members
would be fixed to each cylinder side or end, perhaps,
and each piston rod. Note that a rigid member could
be fixed between every connection point on the multi-
cylinder system and its connection to the polished
rod, and the polished rod's connection to the sucker
rod, in order to insure that the entire mechanism
reciprocates rigidly, if the time required for the
downstroke is to be increased over that of free fall
velocity of the rods.
Another embodiment of the present invention
is as follows. When the hydraulic fluid exits from
the cavities of a working hydraulic cylinder, it can
be very hot from friction. The hot fluid can be
cooled by feeding it to a conventional heat exchanger,
such as a shell and tube exchanger. The cooling
fluid o the invention is the cool well effluent
which usually includes water and oil. The effluent
is 10wed into heat transfer contact with the hydrau-
lic fluid, and the fluid can thereafter be returned
to the hydraulic cylinder cavities~ The cooled
.~
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- 26 -
hydraulic fluid will cool the hydraulic cylinder, and
thereby increase the useful life of the cylinder~
In view of the above disclosure, the advan-
tages of the invention will be appreciated as follows.
Gravity centering of khe multi-cylinder
unit is important because the polished rod must
travel through the center of the well annulus in a
vertical reciprocating motion, strictly aligned with
gravity. If the pumping action is off-center, the
polished rod will wear its seals in an effort to
center itself, and will throw the sucker rod off
center, causing the sucker rod to hit and wear the
walls of the tubing downhole. Further, if the system
is not centered, and the sucker rod system scrapes
the walls of the surrounding tubing, the sucker rod
system can break, or be damaged by twisting and
bending. Even further, there can be undesirable
twisting and breaking in an effort for one part of
the system to center itself while the remainder of
the system remains uncentered (as throwing the pumping
unit itself out of position).
It is noted that in a prior art HEP pumping
unit, a single hydraulic cylinder (with a counterbal-
ance system) has been rigidly fixed to a frame, for
recriprocating a downhole pump. In this arrangment,
a cable such as wire-line 13 (seen in Figure 1) is
used to suspend the polished rod from a polished rod
connector, which connects the vertically fixed piston
rod of the system. Thus, the HEP unit requires close
tolerance vertical positioning rarely attainable and
seldom maintainable in field applications where
extremes of weather, frost and mud hamper close
tolerance centering. Conse~uently, the piston rod
seals which are located in the cylinder above the `
cable (wire line) will be worn as the piston lifts
~79~
and lowers the polished rod and sucker rod, since the
rigidly connected piston and cylinder assembly will
be on a slant, as compared to the gravity alligned
polished rod. Thus, the weight of the polished rod
will be pulling downwardly, while the piston will be
pulling the polished rod connector (located immediately
above the cable) on a slant.
Therefore, it can be seen that the gravity
centering member of the present invention which is
located above the cylinder apparatus, and which is
attached to the top of the frame, provides for the
centering of the entire assembly, so as to minimize
wearing of seals or the sides of the cylinder, or
polished rod seals or any other part of the entire
system. It can also be seen that the present invention
permits the assembly to freely swing in any direction
(Yia a connection such as a ball and socket linkage
or a multiplicity of hinges which accomplish the same
thing), so that the assembly will be completely
centered within itself and on its supporting frame,
and there will thus be less wearing of the polished
rod seals in any direction, and the sucker rod should
not be thrown off in any direction. When the large
amount of weight of the sucker rod and the oil being
pumped are taken into account, in conjunction with
the great number of strokes for an oil pumping unit,
the mitigation of wear to the walls of the tubing, to
the rods, and to the piston assembly, is understood
to be essential.
As compared to currently available alternates,
pumping unit of the present invention is further
advantageous in that it is easy to transport, easy to
set up and maintain, and can be matched to the demands
and needs of any well. The frame and multi-cylinder
rigging shown in Figure 2 are light in weight and all
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;, .
~ 9~96
- 2~ -
that need be transported from one location to another.
Thus, the hung cylinders can be collapsed and removed
- from the frame, or if desired further taken apart to
provide individual cylinders. (Of course, the polished
rod, common to all above ground pumping units, is
disconnected from the cylinder assembly f rst.)
After removal of the cylinder assembly which has been
hung, it is only necessary to transport the light
frame on a truck, or like vehicle. As pointed out
above, the hydraulic fluid source can be at a location
distant from the pumping operation, and it is only
necessary to provide hydraulic lines or hoses running
from the hydraulic fluid source to the new well to be
pumped. Thus, it can be seen that the rigid heavy
pumping unit apparatus of the prior art is entirely
avoided. It is important to understand that a very
high maximum length of desired stroke can be provided
for the pumping unit, without having to worry about a
high rigid unit height (which would provide difficulty
in removing and transporting the pumping unit).
Thus, in addition to the ease of disassembly of the
present pumping unit and transporting it, the col-
lapsibility of the present pumping unit permits a
long stroke length, while the pumping unit remains
easy to transport.
In setting up the pumping unit, the frame
is moved over the well annulus, and is centered with
a plumb-bob from the cylinder hanger (the point of
attachment of the topmost cylinder ~or piston rod)).
Next, the multi-cylinder assembly is hung from the
cylinder hanger. Then, hose connections, power
connections, and the polished rod connection are
made, and pumping is started. Thus, it is understood
that the pumping unit is easily installed, and requires
no unusual foundation or custom site requirements.
..
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- 29 -
Once the pumping unit has been set up, it can be
matched to most pumping requirements by providing the
necessary stroke length, stroke speed, and rated lift
capacity. This is done by choosing a hydraulic fluid
flow rate for all of or each of the cylinders (and
different power sources for each cylinder if desired),
by choosing the desired number of cylinders, and by
choosing the desired phasing of the cylinders (with
respect to each other). Further, the volume per unit
of time of fluid entering the cylinder chambers can
be adjusted to change with time, as in the prior art;
however, this is not needed for the present invention
since the cylinder phasing and cycle shortening ~or
lengthening) will accomplish the same desires.
Thus, it can be seen that the innate variability of
the multi-cylinder system of the present invention
provides a decided ad~antage both in time and cost,
due to the ease of adjustment to a particular well,
and ease of setting up for pumping.
The present invention also provides advan-
tages of the pumping unit being easily maintained,
reliable, and flexible to the changing needs of the
particular well being pumped. Since more than one
cylinder is used for the present invention, the
cylinders can be made relatively small, so that
engineering demands are smaller than in the case
where one laxger cylinder would be used. The cylinders
are cheaper to manufacture, purchase and replace in
the case where a plurality of cylinders are used
rather than using one cylinder.
In addition, in the case of a single-cylinder
system, the entire system must be replaced upon any
failure. On the other hand, a single cylinder of the
multi-cylinder system of the invention can be replaced
or shut down, in order to remedy a defect in the
~79~
- 30 -
portion of the system relating to that single cylinder.
Where a single cylinder is used, that cylinder must
bear all of the friction in the system, and the fluid
being fed to that cylinder must bear all of the heat
which is generated. On the other hand, the multiple-
cylinder system of the present invention permits both
the heat and friction to be distributed among a
number of cylinders, ports and hydraulic lines.
Further, should there be an undesirable heat build-up
in one of the cylinders, that cylinder can be shut
off, with the remainder of the cylinders being manip-
ulated, if capacity permits, so as to compensate for
the shut off cylinder, and to maintain the desired
stroke length, stroke speed, and lift capacity. The
pumping unit of the present invention is also advan-
tageous in that it has less parts to wear out than
conventional pumping units. Further, the parts which
are used are generally cheap, off-the-shelf parts.
In using the multi~cylinder system of the
invention, individual cylinders can be added to or
substracted from the system with the only limitation
being the height of the frame and the power of the
prime mover. This provides fle~ibility and facilitates
changing of stroke length demands over time, as is
; 25 now common in the evolution of producing oil wells.
Stroke length can also be altered by shortening the
extension/contraction cycle, and stroke time can be
altered simply by changing the volume per unit of
time of fluid entering and leaving the cylinder
chambers. Thus, the multi-cylinder system of the
invention can deal with the fact that each well
produces differently throughout its life, requiring
slowing down of the pumping unit after a period of
operation or possibly a shortening of the stroke
length. This is normally done by complicated valve
- 31 -
regulation; however, it is easily done via the present
invention. The parameters for the present invention
can be changed simply by changing the volume per unit
time for the steady state of the fluid entering the
cylinder chambers, and by changiny the phasing of the
cylinders relative to each other.
In addition to permitting the replacement
of a single cylinder which has failed, the present
invention permits the pumping operation to continue,
even afte_ the failure of a single cylinder. Further,
the system can be corrected such that stroke length
and stroke strength remain constant, despite the fact
that one of the cylinders is no longer operating.
This is accomplished for example by shutting off all
fluid flcw to and from the defective cylinder in the
system, and increasing the amount and volume flow
rate of the fluid being fed to the remainder of the
cylinders. Further, the phasing of the cylinders
relative to each other can also be changed to increase
the length of the stroke and compensate for the
defective cylinder (this will result i~ a less smooth
stroke; however, it will be an advantageous procedure,
where the smoothness of the stroke is not critical,
and it is critical to continue pumping). Since the
present system permits defective cylinders to be
easily replaced, and permits the system to continue
operating even before the defective cylinder is
replaced, loss of revenue due to system down-time and
oil flow problems created by discontinuous well
pumping will be minimized. With regard to prior art
hydraulic pumping units, either on]y one hydraulic
cylinder is used, or a plurality of cylinders having
fixedly connected piston rods, and with the cylinders
being fixed to each other. The prior art does not
provide a system, whereby one cylinder might be
. .
- 32 -
easily removed from the remainder of the system.
Further, since the prior art piston rods are fixedly
connected to each other, the individual pistons
cannot be operated out of phase, and cannot compensate
for a defect which occurs in one of the cylinders.
Further, if excessive heating occurs in one of the
cylinders, the prior art piston cylinder assemblies
would need to be shut down, since all of the pistons
move together (or there is only one piston). On the
other hand, via the present invention, only one of
the pistons would be shut down, and th~ remainder of
the pistons would continue to operate.
In addition to the above, the present
multi-cylinder system provides for the phasing of the
cylinders to provide a smooth stroke where the sucker
rod is gradually slowed down at the end of the stroke,
and immediately begins traveling in the other direction
after the end of the stroke, with this procedure
having been described above. This procedure results
in a minimum of stress upon the sucker rod and the
pump which it operates. The carrying out of this
procedure would be impossible, via the prior art
hydraulic pumping units, since the hydraulic uni-ts
could not provide for phasing. In the prior art
hydraulic units, lag time between the end of one
stroke and the feedback to the control means to the
system to begin another stroke will prevent smooth
operation of the sucker rod and downhole pump. In
using the prior art non-hydraulic pumping units,
smooth or consistent operation with gradual slowing
toward the end of a stroke would be possible; however,
complicated valving would be required, in order to
slow the hydraulic flow at the end of the stroke, and
subsequently speed up the hydraulic flow after a new
stroke had begun gradually. The present invention,
~7~
however, provides the desired stroke activity with a
minimum of difficulty.
As two final points in connection with the
present invention, it is to be first observed that
the hydraulic fluid fed to and from the cylinders of
the invention, and to and from the heat exchanger of
the invention, can he fed by means of hoses, pipes,
or other easily available conduit members, and pumps
or other conventionally available motivating members.
Thus, the availability and interchangeability of feed
means for the present invention can be observed.
Second, it is within the present invention to use the
well effluent to cool the hydraulic fluid exiting
from a pumping unit, even in the case where the
conventional one hydraulic cylinder assembly is used.
Thus, the heat exchange embodiment of the present
invention represents, in itselfl an improvement over
the prior art.
` The invention has been described in the
above specification and illustrated by reference to
specific embodiments and the drawings. However, it
is to be understood that the in~ention is not to be
limited by the embodiments or the drawings, and is to
~` be limited only by the claims which follow. It is to
be understood that changes and alterations in the
specific details recited above may be made without
departing from the scope or spirit of the invention
~ disclosed herein.
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