Apparatus and method for gravity correction in borehole survey systems
First Claim
1. A gravity-compensated borehole survey system comprising:
- a probe configured and arranged for passage along said borehole, said probe including acceleration sensing means for supplying acceleration signals representative of the specific force asserted on said probe and angular rate sensing means for supplying angular rate signals representative of angular rotation of said probe about predetermined axes;
a cable affixed to said probe for raising and lowering said probe through said borehole;
cable control means for paying out and retrieving said cable to lower said cable into and retrieve said probe from said borehole; and
signal processing means connected for receiving said acceleration signals and said angular rate signals from said probe, said signal processing means providing;
(a) means for processing said acceleration signals and said angular rate signals during a series of repeated signal processing cycles to supply probe position signals representative of the position of said probe during each of said signal processing cycles, each of said probe position signals including a depth signal representative of the current vertical depth of said probe, said means for processing said acceleration signals and said angular rate signals being responsive to a gravity correction for correcting said acceleration signals relative to signal components that are attributable to gravitational force;
(b) means responsive to said depth signal for supplying a gravity gradient signal, said means for supplying said gravity gradient signal further being responsive to a signal representative of the density of the geological formations penetrated by said borehole at a depth corresponding to said current depth signal and being responsive to a signal representative of the gravitational force asserted on said probe when said probe is positioned at the surface of the earth near said borehole, said means for supplying said gravity gradient signal being configured and arranged so that the value of said gravity gradient signal is in substantial correspondence with the mathematical expression;
##EQU15## where fo represents the gravitational force asserted on said object when said object is located on the surface of the earth and Δ
f is a change in the gravitational force asserted on the probe as its vertical depth changes,Ro represents the radius of the earth,ρ
(H) represents the density of the geological formation surrounding said object during the current signal processing cycle,ρ
ave represents the average density of the earth, andΔ
H represents a vertical displacement of the probe upwards;
(c) means responsive to said gravity gradient signal for supplying said gravity correction signal, said means for supplying said gravity correction signal being configured and arranged to supply said gravity correction signal in substantial accordance with the mathematical expression;
##EQU16## where f(H) represents the gravity correction signal and the indicated summation represents accumulation of the product of the displacement, Δ
H, and the gravity gradient signal for each signal processing cycle.
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Accused Products
Abstract
Disclosed is an inertial navigation borehole survey system wherein the signals supplied by accelerometers (40) that are contained within the borehole survey system probe (10) are corrected for gravitational gradients encountered as the probe (10) travels through a borehole (12). The gravity correction is effected in the survey system signal processor (24) and is based on a gravity gradient signal that mathematically corresponds to: ##EQU1## where f represents the specific force due to gravity; fo represents the specific force of gravity at wellhead (20) of borehole (12); Ro represents the average radius of the earth; ρ(H) represents the local density of the geological formation penetrated by the borehole as a function of depth H; and ρave represents the means density of the earth. In utilizing the gravitational gradient to generate a gravity correction signal, the signal processor (24) effects a summation process that mathematically corresponds to: ##EQU2## where (ΔH)i represents the depth change between the "ith" signal processing cycle and the nextmost antecedent processing cycle, and, the summation range extends from the first signal processing cycle performed during the borehole survey through the final signal processing cycle of the borehole survey operation.
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Citations
5 Claims
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1. A gravity-compensated borehole survey system comprising:
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a probe configured and arranged for passage along said borehole, said probe including acceleration sensing means for supplying acceleration signals representative of the specific force asserted on said probe and angular rate sensing means for supplying angular rate signals representative of angular rotation of said probe about predetermined axes; a cable affixed to said probe for raising and lowering said probe through said borehole; cable control means for paying out and retrieving said cable to lower said cable into and retrieve said probe from said borehole; and signal processing means connected for receiving said acceleration signals and said angular rate signals from said probe, said signal processing means providing; (a) means for processing said acceleration signals and said angular rate signals during a series of repeated signal processing cycles to supply probe position signals representative of the position of said probe during each of said signal processing cycles, each of said probe position signals including a depth signal representative of the current vertical depth of said probe, said means for processing said acceleration signals and said angular rate signals being responsive to a gravity correction for correcting said acceleration signals relative to signal components that are attributable to gravitational force; (b) means responsive to said depth signal for supplying a gravity gradient signal, said means for supplying said gravity gradient signal further being responsive to a signal representative of the density of the geological formations penetrated by said borehole at a depth corresponding to said current depth signal and being responsive to a signal representative of the gravitational force asserted on said probe when said probe is positioned at the surface of the earth near said borehole, said means for supplying said gravity gradient signal being configured and arranged so that the value of said gravity gradient signal is in substantial correspondence with the mathematical expression;
##EQU15## where fo represents the gravitational force asserted on said object when said object is located on the surface of the earth and Δ
f is a change in the gravitational force asserted on the probe as its vertical depth changes,Ro represents the radius of the earth, ρ
(H) represents the density of the geological formation surrounding said object during the current signal processing cycle,ρ
ave represents the average density of the earth, andΔ
H represents a vertical displacement of the probe upwards;(c) means responsive to said gravity gradient signal for supplying said gravity correction signal, said means for supplying said gravity correction signal being configured and arranged to supply said gravity correction signal in substantial accordance with the mathematical expression;
##EQU16## where f(H) represents the gravity correction signal and the indicated summation represents accumulation of the product of the displacement, Δ
H, and the gravity gradient signal for each signal processing cycle. - View Dependent Claims (2)
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3. A borehole inertial navigation system corrected for gravitational force, comprising:
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(a) a movable probe including acceleration sensing means for sensing the acceleration to which the probe is subject and producing an acceleration signal responsive thereto, and angular rate sensing means for sensing the angular rate of rotation of the probe and producing a rate of rotation signal responsive thereto; (b) means for moving the probe through a subterranean passage; (c) processor means, connected to receive the acceleration signal and the rate of rotation signal, for determining the position of the probe, including its vertical depth as a function of said signals; (d) gravity correction means for determining a gravitational correction as a function of; (i) the vertical depth of the probe; (ii) a density of earth strata at the probe'"'"'s position in the subterranean passage; (iii) a predetermined value for the force of gravity at a surface entrance to the subterranean passage; and
,(iv) the vertical depth of the probe, said processor means being further operative to correct the position of the probe as a function of the gravitational correction. - View Dependent Claims (4, 5)
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Specification