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RELATED APPLICATIONS
This patent application is related to U.S. Pat. No. 5,269,384, entitled
"Method and Apparatus for Cleaning a Borehole", issued Dec. 14, 1993 to
Cherrington, which is incorporated by reference herein.
TECHNICAL FIELD OF THE INVENTION
This invention relates in general to hole drilling, and more particularly
to a device for removing cuttings from the hole.
BACKGROUND OF THE INVENTION
Underground conduits are widely used for the transmission of fluids, such
as in pipelines and the like, as well as for carrying wires and cables for
the transmission of electrical power and electrical communication signals.
While the installation of such conduits is time-consuming and costly for
locations where the earth can be excavated from the surface, the routing
of such conduits becomes more difficult where such surface excavation
cannot be done due to the presence of surface obstacles through which the
excavation cannot easily proceed. Such surface obstacles include highways
and railroads, where the installation of a crossing conduit would require
the shutdown of traffic during the excavation and installation. Such
surface obstacles also include rivers, which present extremely difficult
problems for installing a crossing conduit, due to their size and the
difficulty of excavation thereunder.
Prior methods for the installation of conduits have included the use of
directional drilling for the formation of an inverted underground arcuate
path extending between two surface locations and under the surface
obstacle, with the conduit installed along the drilled path. A
conventional and useful method for installing such underground conduits is
disclosed in U.S. Pat. No. 4,679,637, issued Jul. 14, 1987, assigned to
Cherrington Corporation, and incorporated herein by this reference. This
patent discloses a method for forming an enlarged arcuate bore and
installing a conduit therein, beginning with the directional drilling of a
pilot hole between the surface locations and under a surface obstacle such
as a river. Following the drilling of the pilot hole, a reamer is pulled
with the pilot drill string from the exit opening toward the entry
opening, in order to enlarge the pilot hole to a size which will accept
the conduit, or production casing in the case of a pipeline conduit. The
conduit may be installed during the reaming operation, by the connection
of a swivel behind the reamer and the connection of the conduit to the
swivel, so that the conduit is installed as the reaming of the hole is
performed. Alternatively, the conduit can be installed in a separate
operation, following the reaming of the pilot hole (such reaming referred
to as "pre-reaming" of the hole). Additional examples of the reaming
operation, both as pre-reaming and in conjunction with the simultaneous
installation of the product conduit, are described in U.S. Pat. No.
4,784,230, issued Nov. 15, 1988, assigned to Cherrington Corporation and
incorporated by this reference.
While the above-described methods are generally successful in the
installation of such conduit, certain problems have been observed,
especially where certain types of sub-surface formations are encountered.
Referring now to FIGS. 1 and 2, examples of such problems in the
installation of conduit in an underground arcuate path will now be
described.
FIG. 1 illustrates the reaming operation described above, in conjunction
with the installation of production conduit as the reamer is pulled back.
In the example of FIG. 1, entry opening 0 is at surface S on one side of
river R; exit opening E is on the other side of river R from entry opening
0. At the point in the installation process illustrated in FIG. 1, a
drilling apparatus, including a hydraulic motor 14 mounted on a carriage
16 which is in place on an inclined ramp 12, has drilled the pilot bore
hole B from entry 0 to exit E, using drill string 10, and the reaming and
installation is in progress. Motor 14 is now pulling reamer 48, to which
production conduit 46 is mounted, back from exit E toward entry 0. Reamer
48 is larger in diameter than the diameter of production conduit 46. Upon
completion of the reaming operation of FIG. 1, if successful, production
conduit 46 will be in place under river R, and extending between exit E
and entry 0.
Referring now to FIG. 2, a close-up view of the location of reamer 48 and
production conduit 46 in FIG. 1 is now illustrated. Leading drill string
section 10C is attached by way of tool joint 52 to reamer 48, reamer 48
having cutting teeth at its face. Swivel 50 connects production conduit 46
to reamer 48, by way of extension 62 connected to a sleeve 66 on conduit
46. As is evident from FIGS. 1 and 2, bore hole B is enlarged to enlarged
opening D by operation of reamer 48. Conventional sizes of conduit 46 are
on the order of 20 to 48 inches in outside diameter, with the size of
reamer 48 greater in diameter than conduit 46. Due to reamer 48 being
larger than conduit 46, an annulus 68 surrounds conduit 46 as it is pulled
into the hole D. Provision of the annulus 68 allows for reduced friction
as the conduit 46 is placed therein.
As noted above, prior techniques have also included a pre-reaming step,
wherein a reamer, such as reamer 48, is pulled back from exit E to entry 0
without also pulling production conduit 46 into the reamed hole. In such a
pre-reaming step, a following pipe generally trails reamer 48 in such the
same manner as conduit 46 trails reamer 48 in FIGS. 1 and 2, to provide a
string for later installation of conduit 46. Such a trailing pipe will be
of a much smaller size than conduit 46 of FIGS. 1 and 2, for example on
the order of five to ten inches in diameter.
It has been observed in the field that both the pre-reaming and reaming
with installation operations are subject to conduit or pipe sticking
problems, especially as the size of the production conduit increases in
diameter, and as the length of the path from entry 0 to exit E increases.
Such sticking is believed to be due, in large degree, to the inability to
remove cuttings resulting from the reaming operation. Due to the large
volume of earth which is cut by way of the reaming operation, and the
generally low fluid flow velocity of drilling or lubricating mud or fluid
into the reaming location, the velocity of cuttings circulating from the
reaming location is minimal. While the mud or other lubricating fluid flow
could be increased in order to increase the velocity of the cuttings from
the reaming location, such an increase in the velocity of the fluid could
result in such undesired results as hole wall erosion and fracturing
through the formation.
Due to the inability to sufficiently remove the cuttings during the reaming
operation, it is believed that the cuttings pack together near the
location of the reamer. Many of the cuttings from the reaming operation
are heavier than the fluid transporting them and, in such large diameter
holes as are required for the installation of conduit, these large
cuttings will fall out or settle toward the bottom of the hole first, and
then build up into a circumferential packed mass, causing a poor rate of
reaming. Referring to FIG. 2, where a production conduit 46 is being
pulled through with reamer 48, it is believed that such packing will begin
at locations P surrounding the leading end of conduit 46, and also along
the sides of conduit 46 in annulus 68. As the cuttings pack together,
squeezing whatever water or fluid is present therein, the density of the
packed mass increases. Upon sufficient packing, it is believed that
pressure builds up ahead of locations P, toward the bit of reamer 48, such
pressure resulting from the mud or fluid continuing to be pumped into the
reaming location with the return flow reduced at locations P around
conduit 46 in annulus 68. It is also believed that this buildup of
pressure will also force cuttings into bore hole B ahead of reamer 48, and
that these cuttings will also begin to pack, most likely at locations P'
near the first tool joint 70 ahead of reamer 48.
The buildup of pressure between locations P and P' surrounding reamer 48
causes significant problems in the reaming operation. Such effects have
been observed in the field during reaming operations, when the reamer
cannot be rotated, pulled or pushed at a particular location in the
operation. It should be noted that the sticking of the reamer occurs both
for the pre-reaming operation described hereinabove and for the combined
reaming and pulling operation. It should further be noted that the
pressure buildup described hereinabove is believed to be worse in high
pressure formations such as clay.
Another undesired effect resulting from the buildup of pressure when the
reamer cuttings are insufficiently removed is similar in nature to
differential sticking in the downhole drilling field. As is well known in
the downhole drilling art, differential sticking of the drill string
occurs when the pressure of the drilling mud surrounding the drill string
is greater than the pressure exerted by the surrounding formation. In the
event that the caking of drilling mud and the structure of the well bore
is not strong enough to maintain its shape when presented with such a
differential pressure, the pressure of the drilling mud can force the
drill string into the formation, holding it there with sufficient pressure
that it cannot be released from the surface.
It is now believed that similar effects can be present in the field of
installation of underground conduit, due to insufficient removal of the
reaming cuttings. If the pressure near reamer 48, when packed off as
described hereinabove, is sufficiently greater than the pressure exerted
by a surrounding formation, the conduit 46 can be driven into the
formation, causing sticking of the conduit 46 thereat. It should be noted
that the installation of underground conduit is particularly susceptible
to such sticking, since much of the formations underlying rivers are
sedimentary or alluvial formations, with relatively thin layers of
differing strength. Accordingly, the drilling and reaming operations in
river crossing installations are exposed to many differing formations
along the length of the path, with the likelihood of encountering a weak
(in pressure) formation being relatively large. Accordingly, such pressure
buildup due to insufficient reaming cutting removal can cause conduit
sticking at particular locations along the underground path.
Furthermore, it should be noted that the insufficient removal of cuttings
impacts the reaming operation itself. If cuttings are not sufficiently
removed from the reaming location, a number of cuttings will tend to be
present in front of reamer 48 of FIG. 2; as a result, reamer 48 will tend
to recut its own cuttings, rather than cutting the earth in its path and
enlarging the hole. This results in poor penetration rates for the reaming
operation. As noted above, as the reaming rate slows, the pressure buildup
between the packed locations will accelerate, further degrading the
operation and increasing the likelihood of the reamer and conduit
sticking.
In addition, the recutting of the cuttings results in a high degree of
reamer wear, both at the teeth and also in the parent metal of reamer 48.
In rotor reamers, such wear has been observed also at the seals and
bearings. This has also been observed for reamers which use carbide-coated
rotating cones as the cutting bits, in similar manner as a downhole
tri-cone bit; while the carbide wears slowly, the insufficient removal of
the cuttings has been evidence in significant wear of the parent metal of
the reamer. Furthermore, as the cuttings become smaller due to multiple
recutting cycles, the cuttings which are removed with the drilling mud are
much more difficult to process by the solids control system.
Other methods for installing conduit in an underground path includes
forward thrust techniques, such as described in U.S. Pat. Nos. 4,176,985,
4,221,503 and 4,121,673. Particularly, U.S. Pat. No. 4,176,985 discloses
an apparatus which thrusts a casing into a pilot hole, with a bit leading
the casing. However, while such forward thrust techniques are useful for
unidirectional application such as the introduction of conduits into the
ocean, such methods place significant stress on the conduit itself, and
also present relatively slow installation rates. The pull-back methods
described hereinabove and hereinbelow are preferable from the standpoint
of reduced stress on the casing, as well as increased installation rates.
A method and apparatus for removing cuttings is described in U.S. Pat. No.
5,096,002 to Cherrington, issued Mar. 17, 1992, entitled "Method and
Apparatus for Enlarging an Underground Path" which is incorporated by
reference herein. While the device described in U.S. Pat. No. 5,096,002 is
effective in removing the cuttings, it relies on several moving parts,
which may decrease its reliability.
Therefore, a need has arisen in the industry for a method and apparatus for
removing cuttings from a bore hole with a reduced number of working parts.
SUMMARY OF THE INVENTION
In accordance with the present invention, a method and apparatus for
removing drilling mud with entrained cuttings is provided which
substantially prevents disadvantages associated with the prior art.
In the present invention, a pump is provided for forcing a fluid into a
borehole, such that the fluid mixes with the cuttings from the hole. A
pipe receives the fluid and entrained cuttings at a first end of the pipe
and returns the fluid and entrained cuttings to the surface at the second
end of the pipe. At the first end of the pipe, air is injected into the
drilling fluid with entrained cuttings to form bubbles therein, thereby
increasing the velocity of the fluid and entrained cuttings through the
pipe.
In a second embodiment of the invention, a suction is provided at one end
of the pipe to increase the speed of the fluid and entrained cuttings
therethrough.
In a third embodiment of the present invention, an Archimedes screw is used
to remove the fluid and entrained cuttings from the borehole.
The present invention provides significant advantages over the prior art.
The air may be injected into the drilling mud (or other drilling fluid)
without significantly increasing cost or complexity of the drilling
operations. The injected air forms bubbles which significantly increase
the flow of the drilling mud to the surface.
BRIEF DESCRIPTION OF THE DRAWINGS
For a more complete understanding of the present invention, and the
advantages thereof, reference is now made to the following descriptions
taken in conjunction with the accompanying drawings, in which:
FIGS. 1 and 2 are cross-sectional drawings showing an apparatus for reaming
and installing a conduit according to the prior art;
FIGS. 3a-3b are side views of a device for drilling a borehole with a
stationary casing and removing cuttings therefrom using air bubbles to
enhance removal of the cuttings;
FIGS. 4a-4b illustrate side views of a device for drilling a borehole with
a rotating casing and removing cuttings therefrom using air bubbles to
enhance removal of the cuttings;
FIG. 4c illustrates a device for removing cuttings from an existing
borehole using air bubbles to enhance the removal of the cuttings;
FIGS. 5a-5b illustrate side views of a device for creating a borehole with
a stationary casing and removing cuttings therefrom using suction to
enhance removal of the cuttings;
FIGS. 6a-6b illustrate side views of a device for creating a borehole with
a rotating casing and removing cuttings therefrom using suction to enhance
removal of the cuttings; and
FIGS. 7a-7b illustrate side views of a device for creating a borehole and
removing cuttings therefrom using an Archimedes screw.
DETAILED DESCRIPTION OF THE INVENTION
The preferred embodiment of the present invention and its advantages are
best understood by referring to FIGS. 3-7 of the drawings, like numerals
being used for like and corresponding parts of the various drawings.
FIG. 3 illustrates a side view of a first embodiment of a device for
creating a borehole and removing cuttings therefrom. A pilot borehole 100
is drilled underneath a river 102 or other surface obstacle. A working
drill string 104 and a trailing drill string 106 are coupled to the hole
opener (or "reamer") 108. As the hole opener is pulled through the pilot
hole 100, an enlarged borehole 110 is formed. A stationary casing 112 is
positioned within the enlarged borehole 110. A diffuser 114 is connected
to the stationary casing 112 and to an air compressor 116 via air pipe
118. The stationary casing 112 terminates in a stuffing box 120 (also
known as a "packing gland") through which the trailing drill string 106 is
disposed. The stuffing box 120 is coupled to a discharge line 122 which
expels the drilling fluid and entrained cuttings into a solids control
device 124 for purifying the drilling mud. The drilling mud output from
the solids control device 124 is pumped into the trailing drill string 106
via high pressure mud line 126 and pressure mud swivel 127 and is also
pumped into the enlarged borehole 110 via mud pump discharge line 128
using mud pump 130. Drill rig 132 is coupled to the working drill string
104.
Briefly, the operation of the reamer/hole cleaning device is as follows.
After forming the pilot hole 100, the hole enlarger 108 is rotated by
drill rig 132 to form enlarged borehole 110. During rotation of the hole
opener 108, drilling mud, or other drilling fluid, is forced through
trailing drill string 106 to emerge at the face of hole opener 108 carry
the cuttings away from the hole opener 108 during reaming operations. As
the hole opener 108 forms the enlarged hole, cuttings 134 are formed which
mix with the drilling mud in the enlarged hole. Drilling mud is also fed
directly into the enlarged hole through mud pump discharge line 128. The
drilling mud and entrained cuttings return via the path formed between the
stationary casing 112 and the trailing drill string 106 and are
transported via discharge line 122 to the solids control device 124 which
removes solids from the drilling mud and returns the recycled drilling mud
to the enlarged borehole 110.
Importantly, the air compressor 116 forces air into the stationary casing
112 via diffuser 114 which causes air bubbles to be mixed with the
drilling fluid and entrained cuttings. As the mixture of drilling mud and
cuttings 134 enter the stationary casing 112, the air bubbles expand
creating a higher velocity of mud through the stationary casing. It is
believed the air bubbles lower the pressure of the mud within the
stationary casing, thereby increasing the velocity of the mud.
The flow of mud through the stationary casing is shown in greater detail in
connection with FIG. 3b. As shown in FIG. 3a, trailing drill string 106 is
disposed within stationary casing 112, forming a channel 136 through which
the drilling mud and cuttings may be transported to the surface. The
trailing drill string 106 is coupled to reamer 108 such that drilling mud
transported through the trailing drill string 106 is output from the
reamer 108 for lubrication during reaming operations. Stuffing box 120
includes a seal 138 for allowing rotation of the trailing drill string 106
while preventing the returning drilling mud/cuttings from exiting at the
point of rotation.
Diffuser 114 is disposed circumferentially about the stationary casing 112.
The diffuser 114 receives compressed air via air pipe 118. The air is
forced into the channel 136 through perforations 139 where bubbles 140 are
formed in the drilling mud. The bubbles 140 increase the velocity of the
drilling mud/cuttings through the channel 136.
FIGS. 4a-b illustrate a second embodiment wherein air bubbles are used to
increase the velocity of the drilling mud/cuttings. In this embodiment, a
rotating or non-rotating trailing drill casing 140 is coupled to hole
opener 108. The trailing casing 140 includes an intake sub 142 having
holes 144. Air compressor 116 is coupled to a stationary air pipe 146
which terminates within the trailing casing 140 at diffuser head 148.
Stationary air pipe 146 is coupled to trailing casing 140 through air pipe
packing gland 149. Diffuser head 148 includes a plurality of perforations
150 through which the compressed air from air compressor 116 may flow. Mud
pump 130 is coupled to working drill string 104 through drill rig 132. If
a non-rotating trailing drill casing 140 is used, a swivel joint should be
provided so that the working drill 104 does not need to turn the trailing
drill casing. For illustration, it will be assumed herein that trailing
drill casing is a rotating casing.
In operation, drilling mud is provided to the hole opener 108 through the
working drill string 104. Drilling mud is also forced into the enlarged
hole by solids control device 124. The mud combines with cuttings from the
reaming operation, which enter rotating casing 140 through the holes 144
in intake sub 142. Stationary air pipe 146 receives compressed air from
air compressor 116, and outputs the compressed air through the
perforations 150 of diffuser head 148. As described above, the air forms
bubbles in the combination drilling mud/cuttings and increases its
velocity to the surface in the rotating trailing casing 140. The aerated
drilling mud/cutting mixture emerges from the rotating trailing casing 140
through discharge line 122 to the solids control device 124.
This embodiment of the invention provides the advantage of drawing the
drilling mud/cuttings mixture into the rotating trailing casing 140 at the
point of reaming. Hence, the cuttings can be drawn into the rotating
trailing casing 140 before they have a chance to settle at the bottom of
the enlarged hole. In order to increase the draw into the intake sub 142,
a jet pump may be used wherein a high velocity stream of drilling mud is
generated approximate the intake sub to create a pressure differential
which draws the drilling mud/cuttings into the trailing casing 140. Jet
pumps are discussed in greater detail in connection with U.S. Pat. No.
5,269,384, filed Nov. 8, 1991, entitled "Method and Apparatus for Cleaning
a Borehole" to Cherrington, which is incorporated by reference herein.
FIG. 4c illustrates an embodiment of the invention used to remove cuttings
from an enlarged hole after the reaming apparatus has been removed. This
embodiment is similar to the embodiment shown in FIGS. 4a-b, except head
152 is rotated within the enlarged hole to receive the mud/cuttings from
the enlarged hole through holes 153. As described above, suction into the
head 152 may be generated by a jet pump, as described in U.S. Pat. No.
5,269,384, referenced above.
FIGS. 5a-b illustrate an embodiment similar to the device shown in FIGS.
3a-b, with the exception that suction is used to increase the flow of the
drilling mud/cuttings through the stationary casing 112. In this
embodiment, a vacuum pump 154 is coupled to the discharge line 156 which
conveys the drilling mud/cuttings from the stationary casing 112. The
vacuum pump 154 creates a suction which pulls the drilling mud/cuttings
through the stationary casing and outputs the drilling mud/cuttings to the
solids control device 124 via the discharge line 122.
The operation of the device shown in FIGS. 5a-b is similar to the device
shown in FIGS. 3a-b. Drilling mud is output to the enlarged hole 110 via
the mud pump discharge line 28 and to the hole enlarger 108 via the
trailing drill string 106. As the reaming operations are performed under
power of the drill rig 132 and working drill string 104, cuttings become
mixed with the drilling fluid and are drawn into the stationary casing 112
by the suction pump 154.
To further increase the flow of the drilling mud/cuttings through the
stationary casing, the compressed air method shown in FIG. 3a could be
combined with the suction method shown in FIG. 5a.
FIGS. 6a-b illustrate a second embodiment of a reaming/cleaner which uses
suction through a rotating (or non-rotating) trailing casing, similar to
the device shown in connection with FIGS. 4a-b. This embodiment is
structurally similar to the structure shown in FIGS. 4a-b, except that a
vacuum pump 154 is coupled to the rotating casing 140 in order to draw the
drilling mud/cuttings from the rotating casing. While the air compressor
116 of FIG. 4a is not used in the illustrated embodiment of FIGS. 6a-b,
however, both the air compressor 116 and the vacuum pump 154 may be used
in conjunction to increase the flow of the drilling mud/cuttings through
the rotating trailing casing 140.
In operation, drilling mud is provided through the working drill string 104
to the hole opener 108. Additionally, drilling mud is provided by the
solids control unit 124 to the enlarged borehole 110. During the reaming
operation, cuttings become mixed with the drilling mud and are drawn into
the rotating casing 140 through holes 144 of intake sub 142. The drilling
mud/cuttings are removed by the vacuum pump 154 to the solids control unit
124 via discharge line 122.
As previously described in connection with FIG. 4c, the device shown in
FIGS. 6a-b can be designed as a hole cleaner (without the reamer) to
remove cuttings from an already enlarged borehole.
FIGS. 7a-b illustrate another embodiment of a reamer/hole cleaner which
uses positive displacement to create a suction to remove the drilling
mud/cuttings from the enlarged borehole. A structure shown in FIGS. 7a-b
is similar to that shown in FIG. 6a, except an Archimedes screw 158 is
used to remove mud/cuttings from the rotating (or non-rotating) casing
140. The Archimedes's screw is disposed within rotating casing 140 and
powered by rotary drive 160. As cuttings are transported up the
Archimedes's screw 158, a suction results which draws more drilling
mud/cuttings into the holes 144 of intake sub 142.
This embodiment has the advantage that the flow of drilling mud/cuttings
through the rotating casing 140 is very controllable.
Although the present invention and its advantages have been described in
detail, it should be understood that various changes, substitutions and
alterations can be made herein without departing from the spirit and scope
of the invention as defined by the appended claims.
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