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Description  |
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BACKGROUND OF THE INVENTION
This invention relates generally to apparatus for logging earth boreholes
and more specifically to methods and apparatus which utilize means in
addition to gravity for assisting the well logging instrument in
traversing deviated earth boreholes.
It has become relatively common within the last few years to drill wells in
search of oil and gas and the like with a portion of the bore deviating
from the usual vertical orientation thereof. The deviation or inclination
may extend for a considerable distance, sometimes returning to the usual
vertical orientation. In some instances, such boreholes may extend past 90
degrees from the vertical and actually be extending in the up direction
for some distance.
It is well known in the art of drilling such wells to attempt the logging
of the formations surrounding such boreholes with logging instruments run
into the well bore on a wireline and/or a cable to perform various
operations. Such tools usually depend upon the force of gravity to permit
positioning of the well tools at the desired formation within the well
bore.
Manifestly, the relatively horizontal angle of the deviated portion of the
well bore will not permit the wireline actuated tools, to move into the
lower portion of the well bore since friction of the logging tool in the
deviated portion works against the force of gravity. Thus it has become
essential to provide some means of causing the well logging instrument to
pass through the deviated portions of the well bore.
An additional problem commonly associated with such boreholes relates to
the instability of some formations penetrated by the well bore, which
results in borehole diameter changes, some of which are very abrupt.
Ledges are thus formed and the logging instrument lodges against these
ledges.
Another problem exists in a deviated borehole when the cable used to raise
and lower the logging cable becomes "key seated". The term "key seated"
refers to the situation where, due to well bore deviation or passing over
a ledge within the borehole, the logging cable wears a groove or slot in
the ledge. The friction caused by the logging cable passing within the
groove makes it appear from surface indications that the downhole logging
instrument is lodged within the borehole. Further compounding the problem
is the fact that since the cable, not the logging instrument, is the
source of friction the cable cannot be freed by "pulling loose". "Pulling
loose" consists of exerting sufficient force on the cable from the surface
to separate the cable from the instrument at the connection point between
the two. The successful procedure results in the loss of the instrument
but allows retrieval of the cable to the surface. The instrument can later
be recovered by an operation termed "fishing" which is well known in the
art of well drilling operations.
Yet another problem encountered when a cable becomes "key seated" occurs
when the instrument is being removed or upwardly traversing the borehole.
The instrument will become lodged at the point of "key seating", its upper
portion actually attempting to pass into the groove created by the cable
passing over the formation.
Thus, it has proven difficult to adequately log the earth formations
surrounding these deviated sections utilizing only gravitational force for
descent. While some prior art methods have addressed the problem of
assisting the downward traverse of the instrument through the borehole,
none have also addressed the further problem of aiding the ascent of the
logging instrument.
SUMMARY OF THE INVENTION
The present invention provides method and apparatus for traversing deviated
sections of a borehole with a logging instrument. The method and apparatus
provided leave in formations surrounding the deviated sections utilize an
elongated logging instrument having expandable pad members. These pad
members house drive wheels which extend beyond the pad members. The
application of a drive force the wheels, causes rotation thereof, further
causing the instrument to be propelled up or down the borehole depending
on the direction of rotation of the wheels. The wheels are angularly
mounted so the resulting movement of the instrument is an "auger" like
pattern.
The foregoing and other features and advantages of the present invention
will be apparent from the following detailed description of the invention
taken with reference to the figures of the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 is a schematic representation of a well drilling operation showing
the drilling of a deviated earth borehole from an offshore platform.
FIG. 2 is a schematic representation of a well logging operation showing a
prior art well logging system encountering some of the problems associated
with logging a highly deviated earth borehole.
FIG. 3 is a schematic representation showing the drive mechanism positioned
for aiding the well logging instrument in traversing the boreholes in
accordance with the present invention.
FIG. 4 is a partial cross-sectional view of the drive mechanism of FIG. 3
showing a drive train for providing rotational force required to move the
apparatus.
FIG. 5 is an enlarged schematic view, partially cut away, showing a toothed
wheel mounted within a wall-engaging pad member.
FIG. 6 is a schematic representation of a drive wheel mounted so that the
angle between the axis of the borehole and a plane generated by the
diameter of the wheel is zero.
FIG. 7 is a shematic representation of the drive wheel of the present
invention showing the mounting of the wheel at an angle other than zero.
FIG. 8 is a schematic representation showing the path of travel within a
borehole of a wheel in FIG. 7 mounted at some angle other than zero.
FIG. 9 is a schematic representation of an alternate embodiment of the
present invention whereby the well-engaging pad-members are affixed at the
upper extremity of the logging instrument.
DETAILED DESCRIPTION OF THE INVENTION
Referring now to the drawing in more detail, FIG. 1 illustrates a
conventional system for drilling an earth borehole having a high degree of
deviation from true vertical. As is well known in the art, it is a common
practice to drill such slanted wells from offshore platforms. A drilling
platform having a plurality of legs 11 anchored on the ocean floor 12 has
an earth borehole 13 drilled therefrom. Within the borehole 13 is a pipe
string 14, to the lower end of which is attached a drill bit 15. A surface
casing 25 maintains the integrity of the borehole 13 as is well known in
the art. A derrick 16 with conventional drawworks 17 is mounted on the
platform 10. The drill string 14 comprises a number of jointed sections of
pipe terminating at its upper end in a kelly 18, followed by a swivel 19,
a hook 20 and a travelling block 21 suspended by a drilling line 22 from a
crown block 23. The drawworks 17 also drive a rotary table 24 which in
turn transmits the drive to the kelly 18. One end of the line 22, namely
the fast line 22a, is connected to the drawworks 17 which contains the
motor or motors for manipulating the drill string. Although not
illustrated, the other end of the drill line is secured to an anchor on
the platform floor, that portion of line extending to the anchor from the
crown block being generally referred to as the dead line. Again not
illustrated, such an anchor member normally would include a winding-on
drum and can also, if desired, contain a dead line sensor for monitoring
the weight on the drill bit, for example, as shown in U.S. Pat. No.
3,461,978 to F. Whittle, issued Aug. 19, 1969.
In the operation of the system according to FIG. 1, it is quite
conventional in drilling wells from such offshore platforms to drill the
initial portion of the well substantially along a vertical line from the
platform and then to angle off in the further drilling of the well. Such
wells after angling off will oftentimes be inclined at an angle of 60
degrees to 70 degrees from vertical. It is with these types of highly
deviated wells that the problem presents itself as to providing a log of
the formations surrounding the well bore.
Referring now to FIG. 2, there is illstrated schematically a well logging
operation conducted in accordance with the prior art in which a portion of
the earth's surface 12 is shown in vertical section. A well 13, which has
been drilled as illustrated in FIG. 1, penetrates the earth's surface.
Disposed within the well is a subsurface instrument 30 of the well logging
system. The subsurface instrument 30 may be of any conventional type, for
example, one which is adapted to conduct an induction, electric, acoustic,
or any other of the conventional logs well known in the art. It should be
appreciated that the particular type of well logging instrument forms no
part of the present invention.
Cable 32 suspends the instrument 30 in the well 13 and contains the
required conductors for electrically connecting the instrument 30 with the
surface electronics 36. The cable 32 is is wound or unwould from drum 33
in raising and lowering the instrument to traverse the well 13. During the
traversal, the signals from the well logging instrument 30 are sent up the
cable 32. By way of the slip rings and brushes 34 on the drum 33, the
signals are connected by the conduction 35 to the surface electronics 36.
A recorder 37 connected to the surface electronics 36 is driven through
the transmission 38 by the measuring reel 39 over which the cable 32 is
drawn, so the recorder 37 associated with the surface electronics 36 moves
in correlation with depth as the instrument 30 traverses the well 13. It
is also to be understood that instruments such as the instrument 30 are
generally constructed to withstand the pressures and the mechanical and
thermal abuses encountered in logging a deep well.
In the operation of the system illustrated in FIG. 2, the cable is touching
one ledge of the formation 42 or may even be "key seated" therein, and the
instrument 30 has come to rest against another such ledge against another
such ledge 43 located within the borehole. Ledge 43 makes it exceddingly
difficult, if not impossible, for the instrument 30 to traverse the earth
borehole merely by its own weight.
Referring now to FIG. 3, there is schematically illustrated a well logging
instrument 30, in accordance with the present invention, suspended in a
section of borehole 13, by means of a cable 32. The instrument 30 is
comprised of an elongated body member 49 which houses downhole electronics
logging circuits (not shown). The subsurface circuits may be of any
conventional type, for example, one which is adapted to conduct an
electric, induction, acoustic, or any other of the conventional logs well
known in the art. A swivel joint 51 couples the lower section of the body
member 50 with the circuit housing portion. Electrical conductors (not
shown) pass through the swivel joing 51 by way of slip rings and brushes
coupling the arm position unit 52 and the motor assembly 53 with the
surface. The arm position unit 52 is of the type well known in the art of
the well bore logging and can be either hydraulic or electrical. The lower
housing portion 50 is adapted with a plurality of pad members 54 each of
which houses a toothed wheel or gear 55 and is pivotally coupled to the
body 50 by arms 56.
The operation of the present invention can best be understood by first
referring to FIG. 4, a partial enlarged schematic view, partly in cross
section, illustrating the drive assembly utilized to cause the instrument
to power its way in and out of a borehole. The housing 50 enclosed the arm
position drive unit 52 and an electric motor and transmission assembly 53.
A drive shaft 60 extends from the assembly 53 passing through a bearing 61
and end fitted with a spur gear 62. Spur gear 62 is in mesh with a
plurality of other spur gears 63, one for each arm unit. Each second spur
gear 63 is affixed to a shaft 64 passing through a bearing 65 and
terminating a flexible coupling such as a U-joint 66. The U-joing 66
couples drive shaft 64 to a shaft 67 located within the arm member 56.
Shaft 67 is adapted with a slidable spline joint 68 allowing arm 156 to be
extended from and retracted to the instrument body 50A. The lower
extremity of shaft 67 is fitted with a second U-joint 69 connected to
shaft 70 fitted with a bevel gear 71. Bevel gear 71 is in mesh with a
second bevel gear 72 shaftable connected to toothed wheel or gear 55 held
in place within pad member 54 by bearings 73 and 74 protruding beyond the
face of the pad member 54.
The toothed wheel or gear 55 mounted within the pad 54 is better
illustrated by reference to FIG. 5, an enlarged frontal schematic view,
partially in cut away, of a pad member 54 housing the toothed wheel 55.
The wheel 55 is held in place by means of shaft 80 positioned within
bearings 73 and 74 allowing rotation of the wheel 55. The toothed wheel or
gear 55 is mounted at a preselected angle, the purpose of which will be
explained in detail in reference to the operational explanation of FIG. 3.
Gears 71 and 72 provide the rotational drive to wheel 55 and by the use of
bevel gears allow the angular mounting.
Again referring to FIG. 3, in the operation of the invention as
illustrated, the instrument 30 is lowered into the borehole 13 by means of
the cable 32. When the instrument enters a highly deviated portion of the
borehole the force of gravity will no longer be sufficient to cause
descent of the instrument and it will come to rest upon the lower borehole
wall. When tool stoppage is sensed at the surface, the arm position unit
52 is activated causing the pad members 54 to be extended outwardly until
the toothed wheels or gears 55 are urged into contract with the borehole
wall. The outward extension of the arms 56 will cause a centralizing
effect upon the lower portion of the instrument. Once the wheels 55 have
been urged into intimate contact with the wall, power is supplied by means
of cable 32 from the surface to the motor 53.
Returning now to FIG. 4, power supplied to the motor 53 causes rotation of
shaft 60 and spur gear 62 further causing rotational force to be
transferred to spur gear 63 and shaft 64. U-joints 66 and 69 combine with
sliding spline connection 68 to allow rotational force to be coupled by
shaft 67 when the arm 156 is in an extended position. Rotation at U-joint
69 is transferred by the meshing bevel gears 71 and 72 to provide drive to
the toothed wheel or gear 55 contacting the borehole wall.
The toothed wheel 55 has a rotational torque T which is supplied by the
above described motor 53 and connecting shafting 60, 64, 67 and 70.
Referring to FIG. 6, FIG. 7, and FIG. 8, the application of the rotational
force will be described in greater detail. First examining FIG. 6, there
is illustrated the toothed wheel 55 engaging the borehole surface 40 and
mounted so that wheel rotation will result in travel generally parallel to
the borehole axis. The torque T applied to the wheel 55 will cause a force
F to be developed at the wheel shaft 80, this force F being transmitted to
a carrier mechanism 70 which captures the wheel 55 and shaft 80 and will
cause the carrier mechanism 91 to be propelled in the direction of F. An
obstructing force R acting upon the carrier mechanism 70 opposite to F
will tend to impede the movement of the carrier 70, however, the carrier
will continue to advance until the state of F=R is reached. Thus, the
force R required to stop the carrier progression is F. If, as in FIG. 6,
the angle between the axis of the borehole and the plane generated by the
diameter of the toothed wheel 55 is zero, the wheel 55 will travel in a
straight line down the wall 40 parallel to the axis of the borehole. The
velocity of the wheel 55 and shaft 80 travel along the surface 40 will
depend on the rotational velocity of the shaft 80 and the diameter of the
wheel 55.
Now suppose that the angle between the axis of the borehole and the plane
generated by the diameter of the toothed wheel is not zero but is some
angle .theta., as represented by FIG. 7. The force exerted by the wheel
shaft 80 onto the carrier mechanism 74 is again F and the force is
directed toward intended wheel travel. If an obstructing force R exists
that is oppositely directed to that of the motivating force F, the
magnitude it must possess to stop the progression of the carrier 79 is F,
as asserted above. Within the well bore, with an angularly mounted wheel,
the obstructing force R will not generally be directly opposite that of F
but will be directed parallel to the axis of the borehole and the angle
between the obstructing force R and F will also be .theta.. Under this
condition, the force R tends to impede the progression of the carrier 70
down the cylinder and the toothed wheel 455 pressing against the carrier
70 now generates a thrust force N normally 90.degree. to that of F. At
this time there will be three forces F, N and R acting upon the carrier
91. Resolving these forces leads to the following equations:
F Sin.theta.=N Cos .theta.
F Cos .theta.+N Sin .theta.=R
or
N Cos .theta.=F Sin .theta.
R-N Sin=F Cos .theta.
Since F is a known quantity we can readily solve R and N.
Since F is a known quantity we can readily solve R and N.
##EQU1##
and
R=F/Cos .theta.
N=F tan .theta.
The obstructing force R required to stop the progression the carrier 79 now
depends upon .theta. as well as F. If .theta. if 0.degree., the force R
required to stop the carried 79 is F as above described. If .theta. is
increased to 45.degree. the force R required is 1.4F and if .theta. is
further increased to 60.degree. the obstructing force R is 2F. As has been
described, as .theta. continues to approach 90.degree. the obstructing
force R required to stop the progression of the carrier mechanism 79 can
be several multiples of F. For actual operation, the selection of a
particular angle .theta. will depend upon the ratio of the magnitude of
the expected obstructing force R and the available force F at the wheel
shaft 80. It is apparent that as the wheel rotates, the path of
progression is not directly down the borehole wall parallel to the axis of
the borehole but as illustrated by FIG. 8, is now helical around the axis
of the well bore along line 100.
When the toothed wheels are mounted in a number of arm member pads 54, as
in FIG. 3, a drive force will be provided causing the instrument to move
within the borehole utilizing an "auger" action. The lower portion will
move downhole through deviated sections, rotating about the swivel joint
51 and pulling the remainder of the logging instrument 30 through the
deviated section.
FIG. 9 is a schematic illustration of an alternate embodiment of the
disclosed invention. In FIG. 9 there is shown a portion of the cable 32
which has became "key seated" in a borehole ledge 42. In the present
embodiment, the device to aid passage through the borehole is affixed atop
the instrument 30' by means of the swivel joint 51' and is coupled to the
logging cable 32 by a second swivel joint 76 mounted off the center line
of the instrument 30.
In the prior art, as the instrument proceeds up the borehole, the upper
portion would become lodged against the well bore wall at ledge 42 due to
the cable 32 passing within a slot created by the cable 32 being pulled
across the formation. In the operation of the instrument illustrated by
FIG. 9, the twisting or auger effect of the apparatus as it proceeds up
the borehole will cause the cable 32 to be whipped about corresponding to
rotation of the apparatus. This whipping will tend to cause the cable 32
to be pulled from the point of "key seating" within ledge 42, freeing the
cable and further allowing passage of the logging instrument up the
boreholde.
Thus, there have been illustrated and described herein the preferred
embodiments of the present invention which provide methods and apparatus
to facilitate the movement of the well logging apparatus through the
borehole and to aid in dislodging the cable from a "key seated" state.
However, those skilled in the art will recognize that obvious
modifications can be made to the preferred embodiments without departing
from the spirit of the invention. For example, instead of a single toothed
wheel or gear within a pad member several wheels could be contained
therein to provide added rotational drive. Furthermore, instead of using a
single motor drive and associated linkage each pad could contain a
separate motor to drive the corresponding wheel.
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