CA1057354A - Surveying of subterranean magnetic bodies from adjacent off-vertical borehole - Google Patents

Surveying of subterranean magnetic bodies from adjacent off-vertical borehole

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Publication number
CA1057354A
CA1057354A CA275,893A CA275893A CA1057354A CA 1057354 A CA1057354 A CA 1057354A CA 275893 A CA275893 A CA 275893A CA 1057354 A CA1057354 A CA 1057354A
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CA
Canada
Prior art keywords
magnetic field
borehole
target
delta
separation
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CA275,893A
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French (fr)
Inventor
George F. Roberts
Fred J. Morris
Robert L. Waters
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Houston Oil and Minerals Corp
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Houston Oil and Minerals Corp
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Classifications

    • EFIXED CONSTRUCTIONS
    • E21EARTH DRILLING; MINING
    • E21BEARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B7/00Special methods or apparatus for drilling
    • E21B7/04Directional drilling
    • EFIXED CONSTRUCTIONS
    • E21EARTH DRILLING; MINING
    • E21BEARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B47/00Survey of boreholes or wells
    • E21B47/02Determining slope or direction
    • E21B47/022Determining slope or direction of the borehole, e.g. using geomagnetism
    • E21B47/0228Determining slope or direction of the borehole, e.g. using geomagnetism using electromagnetic energy or detectors therefor
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V3/00Electric or magnetic prospecting or detecting; Measuring magnetic field characteristics of the earth, e.g. declination, deviation
    • G01V3/18Electric or magnetic prospecting or detecting; Measuring magnetic field characteristics of the earth, e.g. declination, deviation specially adapted for well-logging
    • G01V3/26Electric or magnetic prospecting or detecting; Measuring magnetic field characteristics of the earth, e.g. declination, deviation specially adapted for well-logging operating with magnetic or electric fields produced or modified either by the surrounding earth formation or by the detecting device

Abstract

ABSTRACT

A method and apparatus for performing a surveying operation to locate, a target subterranean ferromagnetic body having remanent or impressed magnetization. The surveying operation is conducted from an off-vertical bore-hole adjacent the target magnetic body using magnetic field sensing apparatus, and involves determining the range and direction of the subterranean target with respect to the location of the magnetic field sensing apparatus. Target direction is determined by measuring three magnetic field components and resolving the measured components into a resultant vector. Target range is determined by measuring total magnetic field intensity and target body magnetic field intensity gradient in the direction of the off-vertical borehole. Both static and time-varying fields may be detected by the subsurface apparatus. The methods and apparatus dis-closed may be used in such diverse areas as the location of ore deposits, guidance systems for drilling off-vertical wells to intersect a previously drilled well, and location metallic objects underwater.

Description

7~S~`

BACKGROUND OF THE INVENTION

The present invention relates, in general, to surveys for locating target subterranean bodies, and more particularly to directional subsurface drilling of off-vertical wells using a magnetometer instrument to survey from a borehole the direction and range to a predetermined sub-surface target and provide information for guiding further drilling.
In drilling an oil or gas well, it is often desirable to drill the hole as nearly as possible in a true vertical course. Realizing that a well cannot be drilled that is exactly vertical, at the conclusion of the drilling of the -well, it is routine practice to have a logging survey made in order to determine the deviation off-vertical of the well at various depths. The survey involves, in one case, the operation of an instrument, as it is raised or lowered through the bore-hole, to register changes in its orientation off-vertical using the earthls magnetic field and gravity as references.
In another case, changes with respect to a gyroscopic reference are recorded. Instruments of this type are well known to those skilled in art.
When a well "blows out" or goes out of control, it is desirable to intersect that well at a point above the high pressure producing formation in a suitably permeable zone, so as to allow fluid flow in order to plug the borehole and eliminate the blowout. Such a relief well is drilled in order that cement or some similar material can be pumped down to kill the blowout. In wells having large flow rates, and particularly those which have caught fire as well, it is required that an off-vertical well be drilled to intersect the first ~ 30 well to provide a path to the point where shutoff is desired to be made.
-2-,~

l~S7;3S~

Generally speaking, off-vertical well drilling -to intercept a previously drilled well can be done fairly accurately if the location of the target is known with sufficient accuracy. ~lowever, due to the lack of accuracy ;~
in the logging of the off-vertical deviations of the first well, the exact position of the desired target point along the blown out well is generally not accurately known.
Typically, the location will be known only to within about ~ ~-ten to forty feet. In view of the fact that the drill string being used to drill the off-vertical relief well cannot be turned on a sharp radius, and thus must be set up direc-tionally at a point far from the first well, it is difficult to precisel~ intersect -the first wcll. Several attempts may be required to effect intercep-tion. If, however, the target location along the first well site were able to be accurately pin-pointed, drilling could proceed more readily to intersection therewith. This, of course, is generally not the case.

Therefore, to expeditiously drill off-vertical relief wells to intersect a first well in order to shut off a well out of control, it is necessary to employ th~ technique of directional drilling. Directional drillinq involves con-trolling the course of a borehold by using surEace and sub-surface instruments to direct the drilling -toward a specific target. Direction recording instrumen-ts are used to deter-mine the desired direction of drilling with deflecting tools and/or directional methods being used dowrl hole to control the downward course of the well.

1(t5735~

One approach to direction recording instruments for use :in off-vertical well drilling is a system in which a magne-tometer is located in a target well with a magnetic field generator, such as an electromagnet, being located in a ,~, second well some distance from the first. The elec-tromagnet is carried by a drill string which is to be guided in accordance with the measurements of the field generated at the target well as obtained by the magnetometer. These measurements provide an indication of the direction of the generated field with the changes in the measured components providing an indication of the direction of travel of the drill with respect to the target magnetometer. This tech-nique of off-vertical well drillincJ is taught in the prior art by U.S. Patents 3,285,350 and 3,406,766 to J. K. Henderson.
Another approach to directional drilling of off-ver-tical wells is that of U.S. Patent 3,725,777 to Robinson et al. The approach disclosed therein provides a method for locating a previously drilled well which is cased with a material having a remanent rnagnetization. Magnetometers measure the total strength of the existing magnetic field ,which is a combination of the magnetized casing plus the earth's field. Possible locations of the previously cased well are calculated; and assuming the strength and direction of the earth's field, the strength and direction of the fi'eld contributed by the cased well can be determined. The distance and direction to the cased well are determined by machine calculations involving a least squares fit analysis.
Another approach involving the determination of the distance between a cased wel], and a directional well is that of U.S. Patent 3,748,57~ to Mitchell et al, which discloses l~S~7354 a teehnique using resistivity measurements. In this tech-nique, the expeeted resistivity of the formations surrounding the off-vertieal well is determined in calculations made of the anticipated reduction is resistivity eaused by the presenee of the casing. A nomogram is prepared by plotting the ealeulated reduetion versus the assumed distanees for eaeh ealeulated formation resistivity. The measured resis-tivity caused by the casing in the distance between the two wells is then obtained form -the nomogram.
Generally, guidanee systems for off-vertical well drilling will include subsurface magnetic field direetion sensing devices and surfaee recording instruments for displaying the information eoneerning the magne-tie field beiny sensed. The subsurfaee magnetie field direetion sensing deviee is usually some type of magnetometer whieh deteets the direetion of emanation of the magnetie field of the target and of the earth, with the outputs therefrom being conneeted to the surface recording instruments.
Typically, the magnetic field direction sensing device will be a fluxgate magnetometer having a low reluctance magnetically direetionally sensitive loop with drive eoils and sense eoils wound thereon. An oseillator produces AC
current flow in the parallel drive coils which developes an alternative magnetic flux in the loop. When the loop is not subject to any ambient magnetic field, -the voltage induced in eaeh sense eoil will be equal and opposite, so that upon summing of the voltages no output is obtained. When the magnetie loop is subjected to an ambicnt magnetic field having lines of force including a vec-tor component paralle~1 to the loop, the balanee between the sense coils is dis-turbed and an ~C voltage is produced at tl-e output. Since ``` 11~57354 :

the magnetic field direction sensing device will be sensi-tive to the earth's magnetic field, some type of neutraliza-ting technique is usually employed to adjust the flux being created in the loop to remove the influence of the earth's field and drive the output voltage of the sense coils to zero. Magnetometers of this type are sensitive only to magnetic fields having a vector component parallel to the core and is, therefore, not sensitive to magnetic fields perpendicular to the length of the loop.
In order to establish the direction of emanation of the magnetic field, it has been usual in prior magnetometer systems to utilize two mutually perpendicular fluxgate magnetometers defining X and Y coordinate vectors of the detected field. The vectors are generally resolved elec-tronically and displayed on some type of surface recording instrument. Typically, the surface recording instrument will serve to resolve the vector components of the sensed magnetic field in a conventional manner using rectangular coordinates, as by plotting the component amplitudes and solving graphically for the actual field direction in the plane of the sensors. ~epresentative of the foregoing described magnetic field sensing devices and magnetometer systems in Schad, U.S. Paten-t 3,731,752. In this reference, it is further suggested that a third magnetometer could be used to measure X, Y and Z maynetic field components (Col.
4, line 55, et seq.).
Prior magnetometer guidance systems for off-vertical well driiling, such as that described above, position the magnetic field direction sensing device in an existing well that is to be intersected by a second well. Thus, the magnetometer becomes the target witll the eLectromagnet, i~S~73S~ ` ~

creatinq a detectable maqnetic field. The requirement that a magnetic field generator be used to set up a detectable magne-tic field can present insurmountable problems in those situations, such as a blowout well, wherein it is not pos-sible to place a magnétometer device or a field generating source in the target well.
Thus, it is desirable to have a surveying system for guiding off~vertical well drilling which is capable of locating a subsurface ferromagnetic target such as a length of drill string, a drill tool or well casing in the target well. Such ferromagnetic material will demonstrate and pos-sess remanent magnetization since most drill pipe and well casing is electromagnetically inspected before it is installed, leaving a residual magnetic field in the casing. Even were this not the case, the magnetic influence of the earth's field will induce some magnetizatioll which may be detected in a ferromagnetic material in the target well. It is further desirable to have a surveying system that provides `not only the direction of the subsurface target from the bore-! 20 hole, but provides the range to the target also.

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1~5735 SU~I~RY OF Tlll-~` INVENTION

In accordance with the instant invention, there is ~ -provided a novel method of surveying subterranean magnetic and electrically conductive bodies of material from an adjacent off-vertical borehole. In one aspect, the instant invention provides a method of directional subsurface drilling of an off-vertical relief well borehole to intersect an adjacent well having remanent magnetization.
In another particular aspect, the instant invention 10 ~ provides a method of directional subsurface drilling of an off-vertical relief well borehole to intersect an adjacent - well having a magnetic field set up around it by the flow of current through the well casing. In yet another particular aspect, the instant invention providcs a method of directional subsurface drilling of an off-vertical relief well borehole to intersect an adjacent well having an electric field emanating therefrom caused by the application of an electric potential to the well casing.
The instant invention also provides a surveying system suitable for locating a subterranean body exhibiting either a static magnetic field, or a time-varying magnetic or electric field. Specifically, the instant invention provides subsurface field sensing apparatus having field sensors which detect and measure fields emanating from the sub-terranean body, and surface instruments for recording and processing the readings made downhole. :Ln a specific application, the instant invention provides a surveying system which may be particularly advantageously used in connection with the drilling of underground relief wells to intersect a previously drilled well, particularly one that is out of control.

~ S'~;~S~
The surveying method of the instant invention involves the determination of both tlle direction of the target sub-terranean body witll respect to a particular underground location, and the range from that location to the target subterranean body. In the case of a magnetic body having remanent magnetization, and therefore a static field, the determination of the direction to the target magnetic body is made by measuring three magnetic field components, and resolving those components into a resultant vector in ac-cordance with conventional vector analysis calculations.
Range determination is made by measuring the to-tal magne-tic field intensity and the gradient, in the directional of the borehole, of the field of the magnetized target body, and then using these measurements to determine the range. It is to be recognized that the total magnetic field will be that re-sultlng from a combination o -the fiel(l Erom thc magneti~ed -targe~
body plus the field of the earth.
In accordance with -the present invention, the measure-ments of a component of macJnetic field intensity and taryet field gradient are made using two axially displaced ma~netic field sensors separated by a known distance. The average of the measurements of the sensors yields the measurement of a component of magnetic field intensity over the separation between the sensors, and the difference AH in the readings of the two - sensors divided by the distance of separation ~r yields ~H/~r which is the average magnetic field intensity gradient over the separation between the displaced sensors. Measure-ments at a minimum of three locations along the borehole are required, thereby defining two separations over which average total magnetic field intensity and average target field intensity gradient measurements are made. Ratios of mac3netic field intensity to target magnetic field intensity gradient are calcula-ted for the two defined separations, usincl the corresponding values of magnetic Eield intcllsity and gradicnt _9_ l~S'~ 35~ ~
determined for eacll of the defl!~ed separations. The cal-culated ratios are then substituted in an equation that is derived from the general expression relating magnetic field intensity of a body and the distance away from the body that an observation point is established. The general equation being ~=Kr n, where K is a constant dependent upon pro-perties of the magnetic body and n is the fall-off rate with distance r of the intensity of the magnetic disturbance, also dependent upon the particular characteris-tics of the target magnetic body.
In the situation where the target to be located ex-` hibits a time-varying magnetic field, a slightly different approach must be employed in the surveying operation. A
time-varyiny magnetic field set up about a subterranean magnetic bocly by vlrtue of an alternating current being applied to the body will result in a circularly distributed pattern of equal intensity points around the axis of the target magnetic body. q'he time-varying magnetic field sensor of the field sensing apparatus is designed to have a maY.iMum response when aligned tangentially to the magnetic fluY lines that follow a circular path, and have a minimum response when the sensor lS
aligned perpendicularly to the circular magnetlc field lines.
Therefore, by detecting the time-varying field set up around the target and selecting the orientation of the instrument such that a minimum response is detected on the time-varying magnetic field sensor, the direction to the target magnetic body may be determined as being in the direction of the a.Yis of the time varying magnetic field sensor. The range l:o the targe-t mag-netic body may be determined in accordance with the technique ~0 employed with respect to static magnetic fie:lds; however whcn phase-lock detectivll is employed using a sample of the currcnt source as a reference, only a single magnetic field sensor need be used with measurements being made at a miniMum of thrce loca-tions along the borehole at known clistances of separation.

l~S 73~
In the situation where a target subterraneall body does not exhibit a detectable alternating magnetic field, but does have an alternating electric field existing about it due to the application of an electric potential to the body, electric field probe sellsors may be utilized to detect and measure the electric field gradient. Direc-tion to the target body is determined by orienting the instrument in which the electric . field sensor is placed until the sensor shows a maximum vol~
tage gradient, as when the electrode sensors are aligned in the direction of the target body. Range to the target elec-trically conductive body is made in a manner similar to that for the other two cases; however, electric field intensity and electric field gradient are used rather than magnetic field intensity and magnetic fi.eld intensity gradient.
~ method o~ directional subsurface drilling of a first borehole to intersect an adjacent second borehole containing a ferromagnetic target, comprises the steps of measuring the components of the earth's magnetic field along orothogonal axes at a first location along the relief borehole suficiently remote from the target to be unaffected by any .magnetic field of the target; measuring components of the total magnetic field (earth plus target) along orthogonal axes at a second location along the relief borehole sufficiently proximate the target to detec-t magnetic effects of the target; determining the direction of the magnetic field of the target from the second location; measuring t,he component of the total field in the direction of the axis of the relief borehole at a plurality of locations in the relief borehole to determine the gradient of the target fi~ld in the direction of the axis of the relief borehole; determ:ining the range of the target from one of -thc pluralty o~ locations; and orient-ing the course of clrilling of the relief borehole in the ~ ` :
105735~ `
direction of the target mag~etic field from a position in the relief borehole from which the second well may be conveniently intercepted. In a more specific method, directional sub-surface drilling also includes periodically interrupting the drilling of the off-vertical relief well borehole to re-determine the direction of greatest increase in magnetic field intensity followed by a reorienting of the course of drilling of the first borehole.
The apparatus for conducting underground surveying to locate, in terms of both range and direction, a target sub-terranean magnetic body includes subsurface field sensing apparatus comprising: an ou-ter housing; a pair of mutually perpendicular radial magnetic field sensors disposed along the frame; and a pair of aligned, axial magnetic field sensors spaced apart a predetermined separation along the frame and perpendicular to the radial field sensors, which axial and radial magnetic sensors define an X-Y-Z coordinate axis system.
In addition, a surveying system in accordance with the present invention further includes surface data handling and data processlng apparatus which comprises: circuitry for receiving the output signals from the sensors in the sub-surface field sensing apparatus, which circuits condition and digltize the received signal; a digital multiplexer cir-cuit for routing the multiple channels of data onto a single data bus; and a programmable calculator connected to the data bus and receiving the digitized data. If time-varying electric fields are being detected, with the subsurface field sensing apparatus providing ~.C. output signals, the input circuitry would further comprise ~C-to-~C converters disposed ahead of the signal condi-tioning amplifiers, or in the alter-native, comprise synchronous detectors disl~osed ahead oE the signal conditional amplifiers. Both the ~C-to-DC converter 1~5 ~3S~

and the synchronous detector convert the A.C. signals to a D.C. signal suitable for conditioning and digitizing. As an alternative to digital processing, the sensor output signals, after conditioning, may be applied to a strip chart recorder and/or a digital voltmeter.
These and other aspects of this invention will be discussed in greater detail in the description below.

, " .

. ' 1~5~7354 BRIEF DESCRIPTIaN OF TIII~ Dl~WINGS

A typical embodiment of the instant invention is illustrated in the attached drawings, which drawings are to be considered in connection with the detailed description that follows. In the drawings, like reference numerals designate identical or corres-ponding parts throughout the severa] views.
In the drawings:

Fig. 1 is a perspective diagram of the subsurface field sensing apparatus in a borehole adjacent a cased well that is 0 desired to be intersected with the borehole;

~ Fig. 2 is a diagram relating to the "ranging" technique and illustrating the discussion associated therewith;

Figs. 3 and 4 are diagrams of -the pattern of emanation of the magnetic field existing in connection with the cased well in Fig. 1.

Fig. 5 is a diagram of the coordinate axis system defined by the set of orthogonal magnetic field sensors carried by the sub-surface field sensing apparatus disposed in the Opell borehole;

Fig. 6 is a vector diagram relating to the development of JO correction factors to be used in connection with the calculation of borehole elevation and azimuth correction angles, with Figs. 3 and 4;
Fig. 7 is a cross-sectional view of the subsurface field sensing apparatus;

Fig. 8 is a block diagram of the subsurface electronics carried by the subsurface field sensing apparatus;

Fig. 9 is a diagram of the visualization of the response pattern of the magnetic sensor elements used in the present invention;

. ' ~ .

.

~ ~ 4 -~ Fig. 10 is a diagram of -the arrangemerlt of the magnetic sensors within the subsurface magnetic field sensing apparatus, as depicted by the response patterns of the sensors;

Fig. 11 is a schematic diagram of a suitable oscillator -circuit for use in the subsurface electronics block diagramed :in Fig. 8, appearing with Fig. 5;

Fig. 12 is a schematic diagram of the circuitry for one ;
of the identical magnetic field sensors;

Fig. 13 is a perspective diagram of a magnetic sensor core element suitable for use in conjunction wi-th the magnetic field sensor circuitry of Fig. 12; -Fig. 14 is a side view of the sensor core element of ~ -Fig. 13 with its response pattern visualizat:ion imposed -thereon;

Figs. 15 and 15A illustra-te the signals to be expected from the output terminals of the sensor core element;

Fig. 16 is a schematic diagram of the electronic cir-cuitry for the time-varying magnetic and electric field sensors in the subsurface field sensing apparatus of Fig. 7;

Fig. 17 is a schematic diagram o~ a voltage regulator suitable for the regulation of the subsurface power supply voltages;

- Fig. 18 is an illus-trative diagram of a suitable embodiment for the vertical sensor shown in the block diagram of Fig. 8, appearing with Figs. 13, 14, lS, and 18A;

Fig. 18A is a plot of the output response of the vertical sensor device of Fig. 18, appearing with Figs. 13 - lS and 18;

Fig. 19 is a block diagram of the surface instrumentation that receives the data acquired by the subsurface instrument.
-]5-1~5'73~
DESCRIPTION OF THE PREFEl~R~[) EMB(~DI~IENT
-A. GENERAL THEORY

The general theory upon which the method and apparatus of the present invention are based is that generally descriptive of and applicable to magnetic and electric fields. The principal focus of the present invention is, however, on the utilization of magnetic fields existing about and emanating from a subsurface target source.
The present invention utilizes the characteristics of the magnetic field of the earth and of a target magnetic source to provide information from which the target range and direction with respect to subsurface magnetic sensing apparatus can be determined. Orientation of the subsurface magnetic sensing apparatus located in the borehole being drilled is determined through referencing with respect to the earth's magnetic field, a known quantity both as to intensity and dip angle at a particulzr location on the earth.
Fig. 1 illustrates one application to which the methods and apparatus oE the present invention can be applied, that application being the drilling of a directional relief well to intercept a previously drilled well.

1. Target Range ..
Large pieces of magnetic material, such as magnetized casing or drill string in a borehole, can create anomalies in the earth's magnetic field. ~n anomaly of this sort will appear as a magnetic field of intensity ll superimposed on the earth's magnetic field. The general form of the expression for the magnetic field as a function of distance from the anomaly is given by:

(1) H = KM, rn '.

5~73Sfl where K is a constant dependent upon such properties as magnetic susceptibility of the surrounding medium, M is the magnetic moment: of the magnetic body, and n is the fall-off rate with -;
distance, r, of the magnetic field intensit~ II of the body.
Differentiating the above expression yields the rate of change of the magnetic field intensity with respect to radial position from the center of the magnetic body. That derivative is:

-llKM
(2) dH/dr rn+l and expresses a vector quantity that may be referred to as the gradient of H, or grad H, in the radial direction. By forming the ratio of H/dII, an expression results involving only the range, r, to the magnetic body and the fall-off rate n. That expression is:
(3) II _ (KM) (rn+~ r dl~7~ r (-nKM) n If two measurements are made such that 1 -rl and ~2 -r~
20dHl/dr n dM2/dr n then upon division,
(4) Hl (dH2/dr) = r1 , H2 (d~-ll/dr) r2 or in the alternate, H2 (dHl/dr) = r2 Hl (dM2/dr) rl This derivation indicates that the range, r, of an observation poin-t in space from the Magnetic body can be determined from measurements of the magnetic field intensity taken at three or more points along a substantially straight line representing the axis of the relief well to determine the average gradient of the magnetic field between those points.

1~73~4 ,, ~ , The values of H and dH/dr for the above equations can be measured using two aligned ~a~netic field sensors displaced a fixed distance apart. For greater accuracy, an average of the magnetic field intensities measured on two-magnetic sensors can be llsed for the-value of H. The difference ~H in the readings between the two magnetic sensors divided by the separation ~r between them yields ~ H/~r, which is the average gradient of the magnetic intensity H over the separation and a good approximation of dH/dr.
Referring to Fig. 2, a diagram is presented therein illus-trating the foregoing discussion. In order to obtain two measure-ments of H and ~H/~r, for substitution in the above equations it is necessary to make at least three measurements of the magnetic field intensity~ Therefore, to obtain Hl, the magnetic field in-tensity at points a and b must be measured and averaged The separation of the magnetic sensors defines points a and b, with ~ rl being the distance therebetween. The approximation of dHl/dr is obtained by dividing the difference in the measured field in-tensities at points a and b, designated ~ Hl, by the separation ~ r. To obtain H2, the displaced magnetic sensors are moved to a new location along the common axis, with the sensor previously at point a moving to point b and the sensor previously at point b moving to point c. Similar to the determination of Hl, the mag-netic field intensity is measured at points b and c with the value of H2 being the average of the two measurements. The approxima-tion of dH2/dr is obtained by determining the difference between the intensities at points b and c, ~ H2, and dividing that quan-tity by the separation, hr The value of r, in equation ~ above is found in ~ig. 2 to be rl - r + 3~ r/2, and the value of r2 = r + ~r/2 Measurements would be repeated at intervals as the sensors are advanced along a path to update and monitor the closing of the range. Ranging accuracy can ~e improved with the measurements being ~ade at intervals that are closer toge-ther, approaching a cont:inuous recording.
By substituting the above determinations into equation 4, the following equation (5~ H2 (~HI/~r~ r+
Hl ~H2/~r) + 3~r results, which can be simplified to (6) H2~Hl r+ ~r/2 Hl~H2 r+3~r/2 ~-and rewritten to express the range, r, as follows:

3~r H2~Hl ~r 1~ 2 2 (7) r 2 Hl~H2 20 Assuming that ~r is insignificant when compared to r, the equa-tion reduces to 1.5 r (8) r H2~Hl -1 where H + H
Hlb a HHc + Hb 2 = 2 ~H = H - H
1 b a ~ H2 = Hc _ Hb The range will be expressed in whatever dimensions the separation ~r is measured. Typically, it would be in feet or meters.
Once the range, r, is determined, the fall-off rate, n, may be ascertained to indicate the character of the magnetic target. The value of n is obtained by solving the equation n = r aH/dr , or the approximation formula n = r A~Il/~r Hl -19-1~5'735'~

It is to be apprecia-ted that the ranging technique described above can also be carried out with a single mag-netic sensor. If only one sensor is used, the measurements of magnetic field intensity must be correlated ~ith the distance down the borehole (the Ar distance) at which they are taken in order to ascertain the separation between the points at which the measurements are made. This can be done by suspending the sensor with a cable that is marked to indicate its length. The separation is required to permit the average gradient of the magnetic field, h H/a r, to be determined.
It is to be pointed out that ranging with a single mag-netic sensor will not, because of practicalities, be as accurate as with two sensors of fixed separation. Most im-portant of the practical limitations on using one sensor is the inability to be sure that the sensor is oriented the same at all measurement locations. It is a basic premise of the ranging technique that the field intensity measurements be made along a straight line and that the magnetic field sensors not change in orientation.

2. Target Direct-ion Magnetized structures of various dimensions and configura-tions create magnetic fields having a characteristic emanation pattern. For example, a magnetized elongate structure form-ing a magnetic dipole will have magnetic flux lines emanating from one end to the other. However, if -the structure is suf-ficiently long and the point of observation is moved proximate one end, the magnetic body will appear to be one emanating from an endless linear magnetic source in -the form of outwardly, radially directed flux lines extending from -the elongate mag-netic structure. The magnetic field characteristics can be ~ ~ ~5'73S~
utilized through appropriate detection by magnetic field sensors, with proper interprctation of the measuremellts and knowledge of the earth's field, to determine direction to the magnetic body from some point in space.
The usual situation confronted in directional subsurface drilling is that in which a well casing or a length of drill string is the magnetic body to be detected, as in Fig. 1. With the elongate configuration creating a dipole and with the obser-vation point in space being located at a distant point far away !0 from the structure, the magnetic field emanating therefrom will appear to be a radially directed field, as illustrated in Fig. 3 and Fig. 4, with an intensity given by H=KM/r2. Utilizing a set of three magnetic sensors arranged orthogonally, the earth's j magnetic field and the target's field can be detected and e~pressed as three components. Since the earth's magnetic field is of a known intensity and direction, its contribution in the readings of the three sensors can be subtracted out, leaving only the component values of the target's magnetic field in the coordinate system defined by the orthogonal magnetic sensors.

; 20 The component values can be resolved using conventional vector-analysis techniques to yield an indication of the direction to the target magnetic body.
; Referring to Fig. 5, there is an illustrative diagram of a magnetic target and the coordinate svstem defined by magnetic sensing apparatus adequate to serve as an example to which the theory and approach to determinlng target direction can be applied.
The coordinate axis system defined by -the three orthogonal magnetic ; sensors has its three axes referenced as X', Y' and Z'. The horizontal X' axis and the slanted off-vertical Y' axis are perpendicular to the axis of the borehole which is the Z' axis.
Due to the slant ~ of the borehole, the coordinate axis system formed by the orthogonal magnetic sensors has rotated about the X~ axis; and while having a common origin, the magnetic sensor coordinate system and the surface coordinate system do not coincide.

, ~ 7;3~'~
The magnetic field sensors ~ssociated with the x', Y' and Z' axes will measure the magnetic Eield intensity components of the total magnetic field (i.e. earth and target). The measured component magnetic field intensitites of the target field will be referred to as llx , Hyl and }Iz . The diagram of Fig. 5 will also serve as a vector dia~ram with the reference designations Hx~, Hy~ and Hz. indicating relative magnetic field components attri-butable to the target magnetic body. -~

With the magnetic sensors still a significant distance from the target such that there is no contrihution by the target's magnetic field to the measured component values, the earth's magnetic field components in the ~', Y' Z' coordinate axis system can be determined. While the earth's field does have a gradient, it is so slight as to be regarded as insiynificant and its intensity treated as a constant. As the field of the target becomes measurable with the advancement of the maynetic sensors down the offset bore-hole, the measured earth's field components can he subtracted from the total field components being detected by the sensors, thereby leaving only the components due to the target's field in the X', Y', Z' coordinate system.
Knowing the components of the target field, the location of the target with respect to the origin of the X', Y', Z' coordinate system can be determined.
A complete description of the components of the earth's magnetic field, He~ in the axial and radial directions can be calculated for any depth location of the magnetic sensors in the subsurface borehole. In order to formulate this description, knowledge is required of the total field intensity, IIT, and the dip angle, ~, of the earth's magnetic field at the specific loca-tion on the earth where the borehole is to be drilled. The totalfield intensity and dip angle can be obtained from the U.S. Mavy Hydrographics Office.

S~73S4 It is also necessary to know ~he an~le of inclination, ~, from horizontal and the directi~n, ~, from magnetic north, at the various depths of interest, of the borehole. This informa-tion is obtained prior by taking magnetic field measurements with the subsurface magnetic sensing apparatus. ~lternatively, a determination of borehole direction and deviation from vertical, referred to as inclination, at various depths is obtainable through a survey conducted by a photoclinometer or clinograph.
Both instruments record a series of deviation measurements corre-'O lated with their depth on one trip into and out of the borehole.
From either, it is possible to de-termine the course and direction of the borehole.
With the above information, the component values of the total field, HT, is in the X', Y', Z' coordinate axis system can be ex-pressed by the equations:

lIX' = HT cos ~ sin ~
Elyl = HT [sin ~ sin ~ + cos ~ cos ~ cos ~ ]
Hz~ = IIT [sin ~ cos ~ - cos ~ cos a sin ~ ].
The predicted values of the earth's magnetic field in the X, Y, Z
' coordinate system may be used to check out proper operation of the magnetic sensors. ~lso, deviations from the predicted values can be used to indicate the presence of a magnetic target.
'To illustrate the above equations, assume that the earth's field, He~ is 43,168 gammas and the dip anglc is 37.6 deyrees.
Further assume that the borehole direction is 33.5 degrees and the borehole inclination is 38.9 degrees. From the above equations, with HT = He~ the earth's field component measured by the X' axis magnetic sensor is 18,877 gammas. The component measured by the Y' axis sensor is 38,736 gammas, and Ihe component along the Z' aY.is is 2575 gammas. To check the'values, they may be resolved into a .

l~'S'~35'~

, resultant according to the mathema-tic expression ~~ ~Hx +Hy +Hz2 = HT
Substit:uting the above values yields the earth's field of 43,168 gammas, as it should.
Continuing with reference to the diagram of Fig. 5, from the magnetic field intensity components Hx', Hyl and Hz' measured by the orthogonal magnetic sensors, the azimuth correction ~gle ~c and the elevation angle ac can be determined. Assuming no rotation of the coordinate axis system about the 3' axis, the aximuth correction angle ~c can be determined as:

O tan a C = X ~:
Hz' ~c = tan Hz' 'lhe elevation correction angle ac can be determined as:

Hy~
tan ac = 2 2 Hz' ~ E~z' = tan -1 Hyl ~0 If rotation of the X', Y' Z' coordinate axis system occurs, there will be no change in Hz'; however, the values of Hx' and l~
will be affected. The vector diagram of Fig. 5 illustrates the following calculations whichprovide corrected values for the component values, Hx' and Hyl~ The corrected values used in the above equations for the azimuth correction angle c and the elevation correction value ~c In the diagram and calculations, represents the angle of rotation of the coor~inate axis system.

.

From the diagram and beginning with the expression Hy + I-lx tan ~, cos lIJ
which can be rewritten as Hyl sin ~ .
Hy = cos ~ + Hx cos and simplified to lQ Hy cos 1~ = Hy + Hx sin ~
from which it c~n be shown that the corrected value is Hyl = Hy cos ~ ~ ~x sin ~- :

Further, it can be readily appreciated that Hx- = Hy sin ~ + Ilx cos ~.

The resultant, R, in the vector diagram of Fig. 5 should :~
not be confused with the range, r, determined in accordance with the ranging technique previously described. The resultant, R, relates only to the directionality of the detected magnetic : target, and its magnitude is merely indicative of the total target 2~ . field strength. The value of the field can be calculated according to:

H target = ¦HXI + l~yl + Hz, The foregoing discussion of target direction determina-tion has been with respect to the detection of static magnetic fields; however, an alternate approach may be used if a time - varying magnetic field can be set up abou-t the target. In order to set up a -time varying magnetic field, a well casing or the : like is excited with an a.c. current. The field resulting ~ from this type of excitation will, if diagramed appear as a ';

l~S~3S~

series of concentric rings emanating from the target source.
The circular flux lines of the field will be directed in accordance with the familiar "right-hand rule". The intensity of field produced will fall-off at a rate inversely proportional to the distance from the -target source, i.e. ~I = KI/r.
An a.c. magnetic field sensor having a sensitivity ~`
response that is a maximum along one axis, when aligned with the field, and a null along another axis perpendicular to the maximum sensitivity axis, when aligned with the field, is O suitable to detect the time varying magnetic field and be used to indicate direction to the taryet. Placed in the time varying field described above, a maximum signal would be detected with the first axis defined above oriented tangentially to the circular flux lines, and a minimum would be detected with the sensor oriented with the null axis tangential to -the circular flux lines.
Therefore, with the a.c. magnetic sensor in the time-varying magnetic field set up around the target casing, dire~tion to the target can be determined by changing the o orientation of the sensor until a null response is obtained.
Knowing that a null response will occur only when the maximum sensitivity axis is perpendicular to the circular flux lines emanating from the target sources, the direction to the target will be that direction in which the maximum sensitivity axis is pointing.
The time-varying (quasi-static) magnetic fields produced by alternating electric currents injected into the target well casing can be utilized in the same manner as described above and will have additional advantages of synchronous detection and the ~) elimination of the effects of the ~arth's magnetic field, thereby increasing the precision of the survey.
.,; .

:.

:~S~73S~
-B. SURVEY SYSTEM APP~R~TUS

A survey system in accordance with the present invention for implementin~ the above theory and techniques of locating from an off-vertical borehole a predetermined subterranean target includes both surface and subsurface instruments.
The subsurface instrument is basically a magnetic field sensing apparatus having magnetic sensors and associated operating cir-cuitry which provide a highly sensitive magnetometer capable of detecting minute magnetic fields. In addition, the magnetic sensor arrangement permits the measurement of three ma~netic field components to allow calculation of the magnitude of the detected magnetic field and the direction to the target magnetic source from which the field emanates. The particular magnetic sensor arrangement in the subsurface instrument also provides an apparatus that is suitable for carryin~ Ollt the "ranging" technlque des-cribed previously herein, whereby the distance to the predetermined magnetic target from the magnetic field sensing apparatus is determined.
The surface instrument basically comprises the data pro-cessing equipment necessary for manipulating the data obtainedby the subsurface magnetic field sensing apparatus. A program-able calculator is provided in which the conditioned data is stored and subsequently processed. Processing of the data is in accordance with predetermined programs that manipulate the data to calculate range and direction to the predetermined subsurface target. Peripheral equipment is also provided for data storage and printout of the processed information.
The programs utilized to process the magnetic field intensity ; information being supplied from the subsurface instrument pri-: 3~ marily carry out the calculations for target range and target direction determination. Jlowever, additional programs can be provided to apply correc-tion Eactors to the data being obtaincd to provide greater accuracy.
5~ -:
Though optional, the surface instrument may further comprise a strip chart recorder and various meters for displaying the ~-data obtained from the subsurface instrument.

1. Subsurface Field Sensing Apparatus a. General The subsurface instrument is designed to detect both quasi-static and time-varying fields. To provide such capability, the instrument includes multiple sensors to provide a D.C. magnetic field sensing system and an A.C. field sensing system. When static magnetic fields are to be detected, referred to as the passive mode of operation, the instrument's D.C. magnetic field sensing system is utilized. However, when operating in the active mode, as when time-varying fields are to be detected, the A.C.
field sensing system of the instrument can be used.
Basically, the D.C. magnetic ield sensing system compriscs a set of three mutually perpendicular D.C. magnetic field sensors defining an X-Y-Z coordinate system. The X-axis magnetic sensor and the Y-axis magnetic sensor each comprise a single magnetometer;
the Z-axis magnetic sensor comprises two D.C. magnetometers that -are spaced apart a predetermined distance. The orthogonal set of D.C. magnetometers are used to determine the direction of the sub-surface target from the subsurface instrument by measuring three magnetic field intensity components of the magnetic field emanat-ing from the subsurface target. The maqnetic field intensity com-ponents are those that are measured along the X, Y and Z axes of the coordinate system defined by the orthogonal set of magnetic sensors. With this arrangement of magnetic sensors, the surface data processing instrument can calculate the direction of the detected subsurface target by resolving the magnetic field com-ponents into a resultant vector. The primary use of the two separated magnetometers that are aligned along the Z-axis is to -2~-1~57~5~

carry out the "rangin~" technique p~e~iously described herein to determine the distance from the subsurface instrument to the detected subsurface magnetic target.
The A.C. field sensiny system actually comprises two types of sensors. One sensor is an A.C. magnetic field sensor, and the other sensor is an electric field sensor. In order to use the ~.C. field sensing system, a time-varying field, either magnetic or electric, must be set up aroung the target well.
Typically, a high current cathodic protection type power supply 10 att~ached to the well casing being used as a target is suitable.
The power return may be made through any other grounding connec-tion, such as a second well casing located some distance from the target casing.
Excitation of the target casing by current flowing along the casing prodùces a circular magnetic ~icld around the axis of the tar~et well casing. The A.C. magnetic field sensor can be used to detect the A.C. component of this field and determine directionality to the target. If it proves to be difficult to establish adequate current flow through the target casing to 20 produce a satisfactory magnetic field, as ~hen excessive current leakage to ground exists, the electric field probes may be utilized to detect the electric field gradient set up by the A.C. component of the excitation current.

b. Mechanical Configuration Referring now to Figs. 7A and 7B, there is shown a cross-sectional view of one embodiment of a subsurface field sensing apparatus, referred to as apparatus 100, having a generally cylindrical and elongate configuration. The body portion of the ap~aratus comprises a tubular outer housing 102 of non-magnetic matcrial, preferably 30 stainless steel, have a nose cone 104 at the anterior and a connector housing 10~ at the posterior. Nose cone 104 includes , lt`S ~35'~
adaptor 108 havin~ threads 110 ~ereon whicll provide a means of attachin~ nose cone 104 to housin~3 102. Enclosed within the fiberglass nonconductive nose cone 104 are electric field probes 112 and an ~.C. magnetic field pickup coil 114. Both the coil 114 for the A.C. magnetic field sensor and the electrodes for the A.C.
potenti.al detector are potted into nose cone 104. Wiring from coil 114 and electrodes 112 is also potted up through the nose cone 104 and connected to a terminal strip (not shown) at the rear of the nose cone.
o Enclosed within the outer housing 102 are the electronics for subsurface apparatus 100. The various printed circuit boards con-taining the electronics for the various field sensing devices are carried on a frame 116 comprised of four elonga~e stringers 117 that extend substantially the entire length of the outer housing 102. The f~ame 116 further comprises ~ front bulkhead 118 and a connector bulkhead ~20 between which the stringers are secured. A series of separatiny bulkheads, all referenced by the numeral 122, provide support to the stringers intermediate their ends.
~) The arrangement of the electronics within outer housing 102 has a Z-axis sensor 124, referred to as the Zl axis sensor, and its corresponding printed circuit board 126 disposed at the front of tool 100. A second Z-axis sensor 128, referred to as the Z2-axis sensor, is disposed adjacent the connector bulkhead 120. A printed circuit board 130 disposed slightly ahead of the Z-axis sensor 128 carries the electronics for tha-t sensor.
The separation between the Zl-axis sensor and the Z2-axis sensor is a predetermined and accurately fixed distance which is preferably approximately three feet. The X-axis sensor 132 and the Y-axis () sensor 134 are disposed at a position intermedia-te the ends of the apparatus 100. A printed circuit board 13G positioned betwecn the X-axis sensor and the Y-axis sensor carries the electronics for both sensors.

; -30-73S~ :

Disposed immediately behind the Y-axis sensor 134 is the power regulator circuit board 137. Slightly further back and adjacent to the Z2-axis sensor electronics is the vertical reference sensor 138.
The mechanical positioning of the magnetic sensors is critical not only with respect to the outer housing 102 but also with respect to the other sensors. Proper arrangement of the sensors will have the axis of maximum sensitivity for the Zl-axis sensor 124 and the axis of maximum sensitivity for the Z2-axis sensor 128 aligned with the longitudinal centerline axis of the outer housing 102. The axes of maximum sensitivity of the X-axis sensor 134 and the Y-axis sensor 132 will both be perpendicular to the longitudinal center-line axis of the housing 102. In addi-tion, -the axis of maximum sensitivity of those two sensors must be perpendicular to one another. Therefore, close attention must be paid to the mechanical alignment of the magnetic sensors of the subsurface field sensing appartus.
Electrical power being supplied to the apparatus 100 from the surface power supplies, as well as the output signals of the various sensors with the apparatus 100, are carried over intercon-necting wires 140 connecting to a cable connector 142 having connector pins 144. The cable from which the apparatus 100 is suspended during the surveying operations attaches to connector housiny 106 by the internal threads 146 formed on the inside of the connector housing. The wires that extend between the subsurface apparatus and the surface instruments that records the measured data connect to connector pins 144 through a mating femal connector (not shown).
c. Subsurface Flectronics Referring next to Fig. 8, a block diagram ot the elcctronics for the subsurface field sensing apparatus is presented. The electronics include the circuitry necessary for both the DC magnetic , 57;~S'~ -~
~ield sensing system, generally designated by the reference numeral 200, and also for the ~C field sensing system, generally designated by the reference numeral 300. In addition, electronic circuitry is provided for maintaining proper power levels to the circuitry in both systems.
Referring first to the DC magnetic field sensing system 200, that system includes the four DC magnetometers 124, 132 134 and 128 referred to previously in connection with Fig. 7. The magnetometers each produce an out~ut signal that is proportional -in amplitude and polarity to the maqnitude and direction of the particular magnetic field intensity component that each is oriented to detect. The output signals from these magnetometers represent : the X, Y and Z coordinate vectors from which may be resolved a resultant vector indicative of the total detected external magnetic field and the direction to the target magnetic source. In addition, the axial DC magnetic sensors 124 and 128 are used to make measure-ments o the ~ axis component of the detected field at two separated locations along the borehole. From the measurements obtained, the target range can be calculated in accordance with the ranging technique described herein.
The DC magnetic field sensing system includes, in addition ~1 , , to the four DC magnetometers, an oscillator 180 which provides at its output an alternating excitation current of a predetermined frequency and magnitude. The oscillator output signal is intro-duced simultaneously to the core drivers of each DC magnetometer.
The core driver amplifies the excitation current and supplies that amplified signal to a sensor core element which is driven into saturation by alternating the driving polarity at the frequency of the ascillator.
The sensor cores produce an ou-tput signal that is pro-protional in amplitude and polarity to the magnitude and direction of the magnetic field intensity component along the particular coordiante axis that the core is oriented to detect. Output signals from the cores, having the form of alternating positive and nega-tive pulses, represent the X, Y and Z component vectors of the ~5~3~
, ..

detected magnetic fie]d. Returning to the block diagram of Fig. 8, the sensor output signal is introduced into a detector which respectively rectifies positive and negative pulses, dif-ferentially, integrating each, ~hen adding the two quasi-static voltages summed. The output signal from the detector is fed -to a servo driver from which a feedback signal is introduced into the sensor core secondary winding to provide a means of magnetically nulling out signal level errors introduced through temperature drift and offset voltage in the various amplifiers and extraneous magnetic flux in the core. The servo driver output is also con-nected to an output amplifier which increases the power level of the signal for transmission of the signal over the lengthy cables extending to the surface instrument.
Referring next to the AC field sensing system 170, the same includes electric field probes 172 for detecting the presence of an electric field. The electric field probes 172 are connected to an amplifier 174 which amplifies the developed electrical signal and passes it on to a fre-quency selective amplifier 176. The frequency selective amplifier 176 removes all extraneous noise, leaving only the information carrying signal. The signal is then, of course, available as an output for transmission over its connecting cable to the surface instrument.
The second type of sensor in the AC field sensing system is the AC maqnetic 178. This sensor is responsive to time varying magnetic fields set up around a target source and produces an output signal functionally related to the detected field. The output siqnal from the AC maqnetic sensor 178 is received by an amplifier 179 for amplification and condi-tioning prior to transmission to the surface instrument.

1~5~354 ` Prior to proceeding with a discussion of the cir-cuitry of each DC magnetometer, special attention should be devoted to the magnetic sensor cores. Of particular interest is the maynetic sensor response pattern that is diagrammed in Fig. 9. The response pattern can best be described as being shaped like two spheres joined together. An axis of rotation, s M, can be defined by a line segment passing through the point of contact of the spheres, Sl and S2, and also passing through the centers of both. Perpendicular to M and tangent to Sl and S2 at the point of contact is the null plane P. A second axis, referred to as a null axis N, may be defined that is perpendicular to and intersecting with the axis of rotation, M, which null axis lies in the null plane.
The output response of the magnetic sensor provides an output signal that in general substan-tially follows a cosine wave as the sensor core is rotated about the null axis N. Specifically, the magnetic sensor will produce maximum voltage output when the axis of rotation, M, which may also be termed the axis of maximum sensitivity, is aligned with the magnetic field. This may be more readily understood with reference to Fig. 9. Restated, the sensor output will be at maximum when the magnetic field being detected is directed as is Hl, that is ~ = O.
If the sensor is caused to rotate about the axis, M, the axis of maximum sensitivity, there will be no change in the sensor output. When the sensor is placed in a magnetic field ; that is directed at an angle oblique to the axis of maximum ; sensitivity, as is the field H2, the sensor output will decrease as~a function of cosine w. Rotation of the sensor about an axis in the null plane with the magnetic field H2 at a angle ~ with respect that that axis will again not produce a chanye in the sensor output. If the angle ~ is increased such that the mag-netic field is directed normal to the axis of the maximum sensi-tivity, i.e. ~ = 90, the sensor output will be zero. If the angle ~ exceeds 90 such that the sensor is placed in a field , - l~S~3S~

directed as H4, the sensor output will change from positive to negative, passing through zero.
In Fig. 10, there is presented a diagram of the subsurface apparatus 100 in which the DC magnetic sensors 124, 128, 132 and 134- are represented at their respective locations by their characteristic magnetic field sensitivity response pattern. As discussed previously, the magnetic sensors define a three-axis coordinate system, wherein the axes are designated X' (horizontal), Y' (vertical) and Z`
(axial). Theoretically, the magnetic sensor~ should define coordina-te axes that pass through a common origin; however, as a practical matter, this is not possible. But, it is to be appreci~ted that it is desirable to place X-axis sensor 132 and Y-axis sensor 134 as close to one another as is physically possible to approximate a common origin. The Z-axis sensors 124 and 128 are, of course, separated by a defined distance ar in order to carry out the ranging technique.
To be noted in the diagram of Fig. 10 is the fact 2Q that the axes of the coordinate axis system are defined by the axes of maximum sensititivy of the magnetic sensors.
The axis of maximum sensitivity of both axial sensors 124 and 128 are aligned with the centerline of the apparatus 100.
The centerline axis of the appartus, of course, corresponds to the Z-axis of the coordiante system. The horizontal and vertical axes are defined by the axes of maximum sensitivity of the sensors 132 and 134.
From the diagram of Fig. 10 and the discussion given above relating to the response pattern illustrated in 3~ Fig. 9, it will be apparent that the magnetic field ema-nating from a subsurface magnetic target source 151 will ~35-1~3573S4 ~

usually impinge each sensor core at a different angle w because of the varying orientation of each sensor. This will cause a diferent output signal to be produced by each sensor. The output signal produced will be in accordance with the formula:

VO = (K)(H) cos ~, where VO = the sensor output;
H = the total magnetic field intensity;
K = a factor in volts/gamma expressing the voltage produced for a given field intensity; and = the angle at which the magnetic flux lines impinge the sensor core. . , It will futher be apparent that, as the apparatus lO0 is changed in orientation with respect to a magnetic field H4,the output of the sensors will change in accordance with the above function. For example, as apparatus 100 rotates about the Y' axis, the axis of maximum sensitivity of the axial sensor 124 will become more nearly aligned with the field, resulting in an increased output signal from the sensor. However, as rotation occurs as described, the X-axis sensor 132 will also be changing in orientation with the axis of maximum sensitivity therefor being turned away from the field. A change of orientation of the X-axis sensor in this manner will result in a decreasing output signal. It will be appreciated that rotation about the Y'-axis as described will have no effect upon -the output of the Y'-axis sensor 134. The amplitude of the output signal therefrom will remain constant, as no change in the orien-tation of its axis of maximum sensitivity with respect to 1~573S4 the field occurs. A change in the output of Y-axis sensor 134 will, of course, be produced by rotation of apparatus 100 about the X'-axis.
In addition to the conductors for the output signals from the DC magnetometers of the DC field sensing system and the output signals from the AC field sensing system sensors, conductors must be provided for voltage regulator 150 which regulates the DC power provided by surface power supplies. Further included in the subsurface electronics is a vertical sensor 152 that prQvides infor-mation concerning the vertical orientation of the subsurface apparatus 100.
Specifically, the vertical sensor provides the angular relationship between the sensor reference plane that contains the axis M and the X-axis sensor and vertical.
Normal rotation in the borehole about the Z axis will move the X and Y axes through random orientations and will pro-vide instantaneous vertical and horizontal vector components of the detected field when their angular relationships with the vertical and horizontal planes are known.
Referring next to Fig. 11, an oscillator circuit system 180 is presented. The oscillator circuit shown is commonly referred to as a Wien-bridge oscillator. The oscillator comprises an active element, operational ampli-i fier 182, having a positive feedback network connecting to the non-inverting input and a negative feedback loop con-necting to the inverting input. The negative feedback loop controls the gain of the amplifier and comprises resistors 184 and 186. The inverting input of operational amplifier ` 30 182 connects to the negative feedback loop at the junction of the resistors. The positive feedback network forms the ' 1~:3S'73S~

second leg of the bridge and comprises two R-C networks.
The first R-C network is comprised of resistor 188 and capacitor 190, which are arranged in series. The second R-C
network is a parallel combination of resistor 192 and capacitor 194. The non-inverting input of operational amplifier 182 connects to the junction of the two R-C net- `
works. As shown, both the positive feedback network and the negative feedback loop are grounded on one side and are con-nected to the output lead 196 of the operational amplifier lQ through a feedback resistor 198.
The oscillator circuit 180 provides an amplitude-; stablized sine wave oscillator yielding a high purity sine wave output. Primarily, frequency stability depends upon the temperature stability of the components being used in the positive and negative feedback loops. In this partic-ular application, the oscillator is preferably set up to provide a frequency of three kilohertz. Values for the components to provide this frequency are given in the Parts List at the end of the description of the electronics. To select a different frequency, reference may be had to the expression for frequency determination provided in the Linear Applications Handbook available from National Semi-conductor at page AN 51-8.
Referring next to the circuit of Fig. 12, there is presented a schematic diagram for a DC magnetometer that is suitable for use in the DC magnetic field sensing system.
The circuitry shown therein is representative of that which is used for each magnetic sensor 124, 132, 134, 128. As mentioned previously, the output of oscillator circuit 1~0 3Q is applied to a core driver 200 which comprises a waveform shaping circuit and a push-pull emitter follower current ~573S~

amplifier. The oscillator output signal is applied to the core driver at terminal 201 and is passed to the waveform shaping circuitry by an ac coupling capacitor 202. The waveform shaping circuit has a gain that is slightly greater than one, preferably on the order of about 1.5. Since the amplitude of the oscillator output signal is at or very near the power supply limits, the gain provided in the waveform shaping circuit causes the sine wave from the oscillator to be clipped. After clipping, the waveform approximates a lQ trapezoidal waveform.
The waveform shaping circuit is basically an inverting amplifier configuration utilizing an operational ampliier 204 and having a feedback loop consisting of resistor 206 that connects between the output and the in-verting input of operational amplifier 204. An input re-sistor 208 constitutes the input network and connects be-tween the inverting input of operational amplifier 204 and coupling capacitor 202. The non-inverting input of ampli-fier 204 is connected to ground through a biasing resis-tor 210.
; The push-pull emitter follower circuit is coupled to the waveform shaping circuit by a capacitor 212, and com-prises an NPN transistor 214 and a PNP transistor 216 ar-ranged in a conventional manner. The base of each tran-sistor is connected to the coupling capacitor 212 through a resistor 218 or 220, respectively. A resistor 222 connects between coupling capacitor 212 and ground.
As will be readily appreciated, transistor 214 amplifies the positive portion of the near trapezoidal waveform from amplifier 204, and transistor 216 amplifies the negative portion of that waveform. The emitters of both : ' ~ -39--transistor 214 and 216 are connected to a coupling capacitor 224 in series with resistor 226. Capacitor 224 couples the primary winding of sensor core 250 to the push-pull current amplifier of core driver 200.
Referring briefly to Fig. 13, a brief discussion ~
of the sensor core 250 will be given to permit a more de- -tailed understanding of the core, and also to provide ade~
quate background for understanding the remaining portion of the DC magnetometer circuitry presented in Fig. 12.
The sensor core 250 is comprised of a toroid 254 and a bobbin 256 adapted to receive the toroid into a slot 258 formed in the bobbin. Toroid 254 is a tape wound core `
of 1 mil thick Supermalloy material, having a cross section measuring approximately 1/8" x 1/8". A winding 260 is placed on the toroid and used as the primary winding shown schematically in Fig. 12. Winding 260 preferably has approx-imately 150 turns of No. 32 wire.
S The toroid bobbin 256, as shown in an I-shaped block of material having slot 258 formed vertically through 20 the structure. A winding 262 is placed on the web portion of the structure, which winding constitutes the secondary , winding represented schematically in Fig. 12. Preferably, ~, winding 262 comprises 600 turns of No. 32 wire.
~ The diagram in Fig. 14 is a side view of sensor i core 250 with toroid 254 inserted within the bobbin 256.
;` The centerline axis, M, through the center of toroid 254 is .
the axis of maximum sensitivity, M. Also in dotted outline are two spheres, Sl and S2, which are used, as previously, to represent the response pattern of the magnetic sensors.
`~ 30 Fig. 14 relates the physical configuration of the sensor core 250 to the response pattern diagram of Fig. 9.

-~S73S~

Current injected into the primary winding 260 on toroid 254 produces a magnetic flux, whose direction is given by the familiar right-hand rule. Taking the toroid 254 in Fig. 13 and the clockwise winding of primary winding 260 thereon, flux is produced in the directions as indicated in Fig. 14. As shown, the flux in the left side of the core is directed upwardly, while the flux in the right side is directed oppositely to it. Core driver 200 supplies suf-ficient current to rapidly saturate the toroid core, causing the rate of change of magnetic flux in the core to approach zero. The secondary winding 262 is linked by the magnetic flux produced by the current in the primary coil. A change of this flux with time will induce a voltage in the secondary winding 262.
Referring briefly to Fig. 15, the waveform of the output voltage available from the secondary winding 262 at terminal 252 is illustrated. The output voltage is observed to be a series of alternately positive and negative-going spikes. During most of the period of each cycle of the driving signal, the net flux linking secondary winding 262 and the net rate of change of flux are zero because of the continuity of the toroid core that provides the magnetic path for the flux. During the instant that the left side and the right side are entering the region of saturation, however, spike is induced in the secondary winding due to the fact that both halves are not satura ed at precisely the same time. When no external field component along the sensor axis (M) is present, the positive and negative spikes are equal in amplitude, as shown in Fig. 15a. When there is a component of external magnetic field along the sensor axis, the waveform appears as shown in Fig. 15b, wherein the ~l~S73S4 positive spikes are greater in amplitude than the negative spikes. Circuitry is provided in the detector and servo-driver portion to compensate and balance the amplitudes of the pulses. That circuitry will be discussed when attention is again directed to Fig. 12.
` With reference to the illustration of Fig. 14, wherein an external magnetic field H is aligned with the axis of bobbin 256, the magnetic flux in the right side of bobbin 256 will be greater than that in the other side.
Assuming that the flux in the right side is in the direction to produce a positive spike, the waveform of the output voltage will appear as the waveform illustrated in Fig. 15B.
It will be appreciated that as the magnetic sensor core 250 changes in orientation with respect to an external magnetic j field, such as that illustrated in Fig. 14, the component of the magnetic field aligned with the axis of maximum sensi-I tivity will vary according to the cosine of the angle A~ between the flux and the bobbin axis. This relationship wasexplained in detail in relation to the sensor response 2~ pattern of Fig. 9 in the discussion relating thereto.
' Returning now to Fig. 12, the output signal from , the sensor core 250 is applied to detector 300 through a ; coupling capacitor 302. Detector 300 comprises transistors 304 and 306 arranged in a push-pull configuration. Tran-sistors 304, 306 have resistors 308 and 310, respectively, connected to their base leads, which resistors are in turn ~ `
connected to coupling capacitor 302. A resistor 312 con-` nects from the junction of the base resistors and the coupling capacitor 302 to ground. Transistor 304 detects the positive-going spike of the output voltage, and transistor 306 detects the negative-going spike in the sensor output voltage waveform.

1(~5735~

The positive spike from transistor 304 is applied to a balancing potentiometer 330 through a resistor and capacitor combination comprising resistor 314, resistor 316 and capacitor 318. This combination of components forms an integrator circuit and acts somewhat in the fashion of a peak-reading sample and hold circuit for the positive-going spike. In a similar fashion, the negative-going spike from transistor 306 is applied through a resistor and capacitor network comprised of resistor 320, resistor 322 and capac-itor 324. The network also, in a manner of speaking, acts as a sample and hold circuit for the negative-going portion of the sensor output waveform.
As mentioned above, both the positive and negative portions of the sensor output voltage are applied to a potentiometer 330. Specifically, the two portions of the waveform are app]ied to opposite ends of the potentiometer with the wiper thereof being connected to the servo-driver 350. Potentiometer 330 through servo-driver 350 and the feedback line 360 associated therewith serves to drive current through the secondary winding 362 producing a mag-netic feedback to balance out any imbalance between the amplitudes of the positive and negative spikes. Basically, the balancing is accomplished by adjusting the potentiometer 330 such that sufficient voltage is dropped across it on each side of the wiper to bring the amplitudes of the posi-tive and negative spikes to the same level, reducing the error signal to zero. Should additional imbalance begill to occur, as by external magnetic field, the shift of relative spike amplitudes will result in a change in output signal amplitude and be fed back as a current to the output of the secondary winding of core 250 to create a field to compen-sate for the offset. Because the feedback arrangement ~ ~573S4 maintains the operating point on the B-H loop of the mag-netic core at the center of magnetizing force, and because ```
the core is driven into saturation in both polarities, any change in permeability of the core due to temperature is balanced out exactly.
Servo-driver 350 is basically an amplifier circuit comprising an operational amplifier 352 driving a Darlington amplifier comprised of transistors 354 and 356 along with resistors 358 and 362. The Darlington amplifier provides significant current gain and input resistance with little increase in circuit complexity. The feedback path line 360 connects to the junction formed by the collector of tran-sistor 354 and the emitter of transistor 356. Feedback line 360 includes a resistor 364 along with variable resistor 368. A filter capacitor 366 connects between the junction of resistors 364 and 368 to ground. The feedback line 360 extends between variable resistor 368 and terminal 252 of core secondary wlnding 262.
The gain for operational amplifier 352 is deter-' 20 mined by the network connected between the servo-driver "
ouput lead at the collector of transistor 354 and the in-verting input of operational amplifiers 352. Specifically, the gain is determined by resistors 370 and 372 with capac-itor 374 being used to remove high frequency spikes, pre-venting their amplification and subsequent introduction - into the feedback loop. Resistor 376 connecting between the inverting input of operational amplifier 352 and the junction of resistors 370 and 372 serves to match the input impedance between the inverting and non-inverting inputs of the operational amplifier 352. In order to provide an adjustment of offset in the servo-driver, the resistance network comprising resistors 378, 380 and potentiometer 382 ~57354 is provided. The wiper of potentiometer 382 is connected throuyh resistor 382 to the junction of resistors 370 and 372 to set a bias level at that point.
The output of the servo-driver is taken from the collector and emitter of the Darlington amplifier transis-tors and introduced into the output amplifier 400 through gain potentiometer 402 having a filter capacitor 404 ar-ranged in parallel with it. In addition, a resistor 406 is placed in the circuit path ahead of potentiometer 402. Gain potentiometer 402 serves to adjust the level.of the signal being introduced into the output amplifier. The gain ad- `
justment potentiometer is preferably set to a point such ;
that the output stage will operate without saturation when the magnetic sensor core is placed in an external magnetic field having an intensity as much as twice that of the earth's field. In addition to the gain potentiometer, the output amplifier 400 includes an operational amplifier 408 driving a push-pull emitter follower circuit, which circuit comprises transistors 410 and 412.
Resistors 414 and 416, respectively, connect to the base lead of transistors 410 and 412. The emitter follower circuit supplies the output signal through a re-sistor 418 to an output terminal 420. In addition, the feedback loop for the output amplifier 400 extends between the junction of the emitter leads of the transistors and the inverting input of 408. The network in the feedback loop comprises gain determining resistors 422 and 424 along with a filter capacitor 428 and impedance matching resistor 426.
The output signal available from output amplifier 400 is of sufficient power level to transmit the signal over the cable that connects to the surface instrument.

~' . .

-1(~57354 The schematic diagrams for both the AC magnetic sensor circuitry and the electric field probe circuitry are presented in Fig. 16. As shown, the AC magnetic sensor comprises a coil 450 in parallel with a tuning capacitor 452. The capacitor is used to tune the coil to the fre-quency of the time-varying magnetic field that is to be detected. The output of the magnetic sensor 178 is intro-duced to buffer amplifier 179 which is of a conventional configuration. Buffer amplifier 179 comprises an opera-tional amplifier 454 having its non-inverting input con-nected to the AC magnetic sensor 178. A feedback loop extends between the output of the operational amplifier 454 and its inverting input, which feedback network comprises a `
parallel combination of resistor 456 and capacitor 458. In addition to the feedback loop, a resistor 460 also connects between the inverting input of operational amplifier 454 and - ground. The output signal from buffer amplifier 179 is coupled to output terminal 462 through a coupling capac-itor 464.
; 2Q Turning now to the portion of the circuitry that provides electric field sensing capability, the electric field probes 172 are shown connected to the input circuitry of the buffer amplifier 174. Specifically, the electric field probes connect to a resistor 466 that is shunted across the input terminals 468 and 470 of buffer amplifier 174. One end of resistor 466 connects to ground, with the opposite end connecting to the non-inverting input of opera-tional amplifier 472. Buffer amplifier 174 is of a conven-tional configuration having a feedback network extending between the operational amplifier output and its inverting input. The feedback loop comprises a parallel resistor and :: ~

lt~57354 capacitor network consisting of capacitor 474 and resistor 476. In addition, a resistor 478 connects between the inverting input of operational amplifier 472 and ground. ~
The output of buffer amplifier 174 is coupled to frequency -selective amplifier 176 by a coupling capacitor 480.
Frequency selective amplifier 176 is an active filter utilizing an operational amplifier 482. A frequency determinative network connects to the inverting input of ;
operational amplifier 482, which network determines the 1~ center frequency and the band width of the filter. The `
frequency determining network comprises a resistor 484 extending from the output of operational amplifier 482 directly to the inverting input thereof. In addition, a capacitor 486 connects to the inverting input of operational amplifier 482. An input resistor 488 connects between coupling capacitor 480 and the capacitor 486 with the junc-tion of resistor 488, with capacitor 486 serving as the junction point to which the remaining components of the frequency determinative network connect. Capacitor 490 2Q connects to the output of the operational amplifier 482 and shunts across resistor 484 and capacitor 486. Finally, a series connection of resistor 492 and potentiometer 494 ! . connects to the junction of resistor 488 and capacitor 486.
Potentiometer 494 is operative to adjust the center fre-quency of the band pass frequency selective filter 176. A
biasing resistor 496 connects between the non-inverting input of operational amplifier 482 and ground. Finally, filter capacitors 498 and 499 connect to the positive voltage bus and the negative voltage bus, respectively.
Referring next to Fig. 17, a suitable voltage regulator circuit is shown for providing both regulated 1(~57354 positive voltage and regulated negative voltage of pref-erably about 8.5 volts each. Unregulated power from the surface power supply, both +12 volts power and -12 volts power, is supplied to the voltage regulator circuit 150 at terminals 501 and 502, respectively. The voltage regulator circuit 150 comprises an integrated circuit voltage reg- :
ulator 504 for the positive voltage regulator portion, and a separate integrated circuit 506 for the negative voltage regulator.
10. Referring first to the positive voLtage regulator circuitry, the +12 volts input voltage from the surface power supply is applied to the circuit 504. An NPN tran-sistor 508 has its collector connected to the incoming power, and its base lead connected to the output terminal of the integrated circuit 504. The emitter of transistor 508 is connected to the inverting input terminal of circuit 504, which input is also connected to the wiper of potentiometer 510. A resistor 512 connects between one side of potentio-meter 510 and the negative voltage input of circuit 504.
Another resistor 514 connects between the opposite side of potentiometer 510 and the current sense terminal on circuit 504. A frequency compensation capacitor 516 is provided between the current limit terminal on circuit 504 and the frequency compensation terminal. In addition, a resistor 518 is placed between the current limit terminal and the current sense terminal on circuit 504. The regulated posi-tive voltage output is taken at the junction of resistors i 514 and 518, and is available from terminal 520.
Referring now to the negative voltage regulator portion, the voltage input to integrated circuit 506 is the regulated positive voltage available from the positive ":
i~ -48-1(~573S4 ;

voltage regulator circuitry. The unregulated negative ~ `
voltage being supplied to terminal 502 from the surface -power supply is further applied to a Darlington amplifier circuit comprised of transistors 522 and 524, both PNP
transistors, specifically, the negative voltage is applied to the collectors of the devices. A resistor 526 is placed -between the joined collectors of the transistors and the base lead of transistor 522. The base of transistor 522 is connected to the integrated circuit 506, and the emitter lead of transistor 524 is connected through r~sistor 528 to the negative voltage terminal on circuit 506. In addition, the emitter of transistor 524 connects to a resistor network comprised o resistors of 530, 532 and potentiometer 534, which network provides output voltage adjustment. The resistor network, specifically resistor 532, is connected to ground, and the wiper of potentiometer 534 is connected to the non-inverting input of integrated circuit 506. A capac-itor 536 connects between the frequency compensation ter-minal and the inverting input terminal of integrated circuit 506. The inverting input terminal is further connected to the reference voltage and negative voltage terminals of circuit 506 through resistors 538 and 540 respectively. The regulated negative voltage is available at terminal 542.
Additional information concerning positive and negative voltage regulators of the type described above may be ob-tained by reference to the Linear Integrated Circuits Data book of National Semiconductor, particularly pages 1-45 through 1-49.

PARTS L:[ST
.
Oscillator Circuit (180) .. . ~

Resistors 184 4.7K

188 4.7K
192 4.7K
198 lOK
Capacitors 190.Ol~fd 194.Ol~lfd Amplifiers 182LM ]08 National Semiconductor D.C. Magnetometer (124, 128, 132, 134) .
Resistors 2n~ 22K

218 l.OK
2Q 22Z lOOK
226 1.5Q

312 3.3K
314 lOOS~

320 lOOQ
; 322 15K

3Q 358 lOK
362 1.5K

368 2.OK
370 lOOK
372 l.OK

384l.OMeg 402 lOOK

414 l.OK
; 416 l.OK
418 lOOQ
422 lOK
424 2.OK

Capacitors ~
202 .1 ~fd 212 .1 llfd -224 .1 llfd 302 .1 ~fd 318 .1 ~fd .
324 .1 ~Ifd 366 .1 ~fd 374 .Ol~fd 428 2.0 I~fd 430 .1 ~fd 432 22~fd 434 22~fd Amplifiers 204 National Semiconductor :
352 "

Transistors 214,216 MD6100 Motorola Complementary Pair 304,306 MD6100 ~l 354,356 MD6100 "
J 410,412 MD6100 ,;, . .

A.C. Field Sensin~ System Resistors , ~ . ' .

460 l.OK
a66 lOOK
~i 476 68K
478 l.OK

; 488 lOK

' 494 2.OK

Capacitors 458 1200pf 464 2.0 ~fd 474 1200pf 480 2.0 ~fd 486 .047~fd 490.0471lfd 498 22~fd 499 22~fd Linear Circuits 454 LM108 National Semiconductor l~S'73S4 Voltage Regulcltor _150) Resistors 510 2.nK
512 6.~1 526 2.2K
528 2.2K
530 3.3K
10532 4.7K
534 2.OK
538 2.7K ~ -540 2.7K

Capacitors :~
516 lOO~f 536 lOQpf Linear Circuits 504 LM723 National Semicon~uctor 20. Transistors 508 2N3054 Motorola 524 2N3740 "

: ~

l~S7354 Referring to Fig. 18, there is illustrated one suitable device that may be used for the vertical reference sensor 152.
The vertical reference sensor has primary importance in pro-viding information as to the orientation of the tool housing 102 with respect to a vertical plane. ~avin~ information con-cerning the rotational orlentation of the tool lO0 will permit increased accuracy in determining the direction to a target mag-netic body from the downhole tool.
The device illustrated in Fig. 18 is a mercury potentiometer lQ sensor, which is in essence a transducer that provides a measure-ment of the angle of rotation of the tool housing about the longitudinal axis of the housing 102. The device is designed to permit the measurement of this angle irrespective of the borehole inclination. The technique illustrated involves a small ball of mercury 552 disposed for unrestricted movement in a circular, non-metallic race 554. The mercury ball, due to the influence of gravity, will always move along the race seeking the lowest point.
The mercury ball contacts a resistive element 55~ on one side and contacts a metallic collector ring 556 on the other side. In essence, the mercury is acting in the same manner as the wiper of a potentiometer or variable resistor.
The mercury ball is constrained within the race in order to keep the ball from being broken up by shock and vibration. The ball is surrounded with a low friction material to provide a smooth surface which will not impede the free movement of the ball to the lowest point in the race. The resistive element should have a linear variation in resistance along its entire length to provide a linear response over the entire 360-degree range. In addition, the resistance ma-terial used must be physically compatible with the mercury ball in order that a good ohmic contact can be made.
The embodiment illustrated in Fig. 18 includes four contacts that define four quadrants, I, II, III and IV. Specifically, a positive voltage potential is applied to the resistive element at l~S7354 the zero-degree position. A negative voltage potential is applied to the resistive element 554 at 180-degree position, and a ground potential is applied to two locations along the resistive element 554 at the 90-degree position and at the 270-degree position.
Fig. 18A is a plot of the output voltage from a col-lector 556 as a function of the mercury ball position along the race. At the zero-degree position, that is where the apparatus reference plane is vertical and the reference mark of the apparatus is up, the mercury ball 552 ~ill be at the bottom of the race. Consequently, little or no voltage drop will be experienced between the contact 558 and the mercury ball; and therefore, the voltage on the collector output lead 560 will be near the positive voltage supply potential.
As the housing rotates counterclockwise, the mercury ball will move along the race in quadrant I. As it moves in this manner, the voltage observed at collector output terminal 560 will decrease linearly until finally, at the 90-degree position the output voltage will be zero volts. If rotation of the housing is continued throughout the full 360 degrees, the output response will be as shown.
Alternatively, the vertical sensor may use only two contacts, that is only two voltage potentials need be at-tached to the resistive element. Again, a linear resistance as a function of rotation is necessary. It is further necessary that the two contacts be displaced a sufficient distance apart that the mercury~ball can pass by the two contact points without shorting them together. By this method, the output voltage would be linear with rotation between, for example, zero degrees and 350 degrees.

- ^, 1~J'5~3S4 Additional approaches to the implementation of the vertical sensor would include a gyroscope disposed in the downhole tool to determine the orientation of the housing with respect to a geographical heading. A gyro benchmark reading would be taken at a known heading at the wellhead with subsequent readings taken throughout the survey related to the benchmark to determine orientation. Also a pendulum which is free to move within the housing could be used. If a pendulum were used, an optical type sensor might be the most advantageous. For example, the suspended mass could have coded apertures through which a light source could project a beam of light onto a photocell behind the plate.
Photocell output would then be representative of the rota-tional orientation of the tool.
A similar reference sensor could be provided to deter-mine changes in orientation of apparatus lO0 by rotation about the X-axis. ~ sensor for per~orming the function of ascertaining housing inclination within the borehole would be placed perpendicular to the vertical reference sensor 152.

2. Surface Instrumentation Apparatus The surface instrumentation is designed to receive, route and manipulate the data being provided by the sub-sur~ace field sensing apparatus. The surface instrument, in order to be compatible with the multiple sensor output subsurface tool, is a multi-channel instrument. Routing of data within the surface instrumentation is by mode switching ; and multiplexing. Manipulation of the data is carried out by a programable calculator receiviny multiplexed digital data.

~--1~57354 The surface instrumentation includes additional equip-ment such as power supplies, analog data recorders, and calculator peripheral devices. The peripheral devices could include a printer for supplying an immediate printout and a digital magnetic tape recorder for storing the data and results.
Referring now to Fig. 19, there is sllown a clock dia-gram for the surface instrumentation. The receiving portion ; of the surface instrument comprises a separate signal con-ditioning amplifier 602, 604, 606, 608 for each data channel.
Since data is to be stored and analyzed in a digital pro-gramable calculator, the data must be converted from the analog form in which it is generated downhole into a com-patible digital representation. To perform this function, a separate analog-to-digital converter 610, 612, 614, 616 is provided to receive the output of each signal conditional amplifier and digitize it. Programable calculator 622 operated with a single data bus, therefore requiring that a digital multiplexer 618 be utilized to route the multi-channel data onto a single data bus to the calculator. An interface 620 is provided to link-up the digital multiplexer 618 and the programable calculator 622. The interface 620 receives control signals in one format over a control signal bus 624, and on the basis of the calculator input controls to it, the interface provides control signals of a format compatible with the digital multiplexer 618.
In addition to the digitized data from the field sensors, a digital representation of the depth at which each sampling of sensor output was taken is also provided to the multi-plexer 618 for routing to programable calculator 622. Depth indication begins with the reading of a depth indicator shaft on the logging cable unit, which shaft turns a depth indicator 626 that provides a digital representation of the ` -depth of the subsurface tool.
In addition to the digital processing portion of the surface instrumentation, analog signal plotting capability is provided. The analog signal available at the output of each signal conditioning amplifier is applied to a buffer amplifier 628, 630, 632, 634. The buffer amplifiers amplify -the signal received to a sufficient level for driving a dual channel strip chart recorded 636. Two multiple position switches 638 and 634 are provided to enable each channel of -~
the strip chart recorders 636 to be connected up to any one of the buffer amplifiers to monitor the data from any one of the field sensors. In addition, the outputs of the signal conditioning amplifiers can be applied to a digital volt meter 642 through a selector switch 644.
When the subsurface field sensing apparatus 100 is being operated in the so-called passive mode, the analog data derived from the D.C. magnetometers are applied di-2Q rectly to their respective signal conditioning amplifiers.
However, if the system is being operated in the active mode, the A.C. field sensors are being used, the A.C. signals must be routed first through an AC-to-DC converter or a syn-chronous detector prior to being applied to the signal conditioning amplifiers. Use of one or the other will depend upon whether it is convenient to run a reference conductor to the surface instruments. Preferably, detectors 650 and 652 are Princeton Applied Research Lock-In Ampli-fiers, Model 122. Assuming that the circumstances at hand permit, a reference signal is taken from the current source being used to excite the target well. The reference signal ~57-l~S7354 is applied to the synchronous detectors to permit phase lock operation. Synchronous detection of the sensor data results in a quasi-static output which is positive for in-phase signals and negative for out-of-phase signals, thereby eliminating ambiguity of direction.
A switching network 660 is provided to permit the routing of the A.C. signals to either AC-to-DC converters 646 and 648 or to synchronous detectors 650 and 652.
Switching network 660 comprises two multiple position double pole switches 662 and 664. The incoming A.C. signal is applied to the terminals of switch 662. Then, according to the particular mode of operation the signal of each channel will be applied to the appropriate AC-to-DC converter or synchronous detector. The input leads to the signal con-ditioning amplifiers 606 and 608 are connected to switch 664. Also, depending upon the mode of operation, switch 644 is positioned to connect each signal conditioning amplifier input to either an AC-to-DC converter or a synchronous detector.
It is noted that because of the limited number of conductors available in the logging cable changes must also - be made in the wiring of the subsurface field sensing appa- t ratus in order to connect the A.C. magnetometer sensor circuitry or the electric field probe sensor circuitry to the subsurface tool output connector.
' C. SURVEY SYSTEM OPERATION

In performing target surveying involving the deter-mination of the range and direction to the desired target well from a location along an off-vertical relief well .~

-1~57354 borehole with the apparatus of the present invention, it is necessary to first select the passive or active mode of operation. If the first well is not burning, it may be possible to excite the well casing with an alternating electric current to generate a magnetic field about the casing, which would then serve as a magnetic field target for the subsurface field sensing apparatus.
Assuming that the active mode is selected, a cathodic generator, typically a three-phase, full-wave bridge, will be electrically coupled to the well casing, and a ground lead taken to an adjacent well to provide a return path for the current. Since the ripple frequency of the rectified AC --is six times the fundamental frequency, the AC field sensing systems in the subsurface tool must have a maximum response at the sixth harmonic of the power generator. Rather than using 360 Hz as the peak response frequency, the AC magnetic field sensor 178 (Fig. 8) and the frequency selective ampli-fier 176 (Fig. 8) should be tuned to 324 Hz to minimize the interference and false information which maybe caused by 60 Hz power systems operating nearby. The reduction of this r' peak response requires that the power generator governor be regulated to generate 54 Hz rather than 60 Hz. This fre-quency adjustment is within the range of commonly available generating systems.
If enough current can be driven through the well casing to set up a magnetic field, the AC magnetic field sensor will be used. However, if sufficient current leakage through the casing to ground is being experienced, it may be neces-sary to use the electric field probes and detect the elec-tric field radially emanating from the surface of the casing.

' -59-. .

1(~57354 With the generator exciting the well casing, the sub-surface tool is lowered down the borehole being drilled, and a survey is made. Based upon the data provided by the sub-surface instrument, the course of the borehole is altered.
The direction of drilling is altered until the subsurface field sensing apparatus determines that the borehole is aligned in the direction of the target casing. In the case of the electric field sensor, a maximum volta~e gradient will be detected when the electrode sensors are aligned in the direction of the target and when a minimum gradient is detected, the line through the electrodes is perpendicular to the direction to the target. If the AC ma~netic sensor is being used, alignment of the sensor axis with the direc-tion of the target will exist when the output of the sensor is at zero.
It is also important to note with regard to Fig. 17 ~ i illustrating the surface instrumentation apparatus that in the active mode of operation in order to be able to deter-mine the direction in which the AC sensor is aimed it is necessary to take a signal from the generator exciting the casing and compare it with the signal from the AC sensor.
In the event that synchronous detection is used the signal would be applied to the sync reference input 653. If con-nections are made to provide proper polarities, the sensor output signal will result in a positive output is in-phase - with the reference signal from the generator, then the ~- sensor is pointed toward the target.
In most cases, it will not be possible to excite the casing because of a burning fire at the mouth of the well, which fire can easily spread over a large area. Operation of the survey system under such conditions will have to be ,; .

11~57354 ~

perfomed in the passive mode with the DC magnetometers in ~-the apparatus being used to detect the remanent magnetiza-tion of the casing in the target well.
As mentioned previously, in order to orient the appa-ratus with respect to the surface geographical coodinates, it is necessary to know the field intensity, the direction with respect to magnetic North, and the dip angle of the earth's field. All of these will be unique values depending upon the exact location on the earth's surface where drilling is to take place.

To begin a survey, the subsurface field sensing appa-ratus is lowered into the borehole suspended from a seven conductor logging cable secured to the connector at the top o the tool. The apparatus is stopped at a location in the ; borehole sufficiently far away from the target such that only the earth's field is detected on the magnetic sensors.
By measuriny the vector components of the earth's magnetic field in the X, Y, Z coordinate axis system of the apparatus in the manner previously discussed, the slope and azimuth of the borehole can be determined. Thus, the orientation of the tool with respect to the surface drilling unit can also ascertained.
After the orientation of the borehole has been deter-mined, which orientation does not change radically with distance due to the inability of the drill string to bend at a sharp radius, and the subsurface apparatus has been checked out and determined to be functioning properly, the subsur-face instrument is lowered continuously down the borehole.

As the instrument is being lowered, measurements of the magnetic field intensity components are made. The surface instrumentation digitizes the measurements and supplies them r~

1~5'7354 to the programmable calculator which organizes and analyzes the data. The data may be recorded on magnetic tape for later recall and processing. The processing of data will be in accordance with the equations for ranging outlined pre-viously herein and conventional vector analysis techniques.
By performing machine calculations on the data, answers can be displayed Oll the printer giving the range and direction to the target magnetic source from particular depth loca- -tions along the borehole. A print out of data relating this information for each depth location along thé borehole provides an indication as to whether the drilling operations are proceeding in a proper direction or will need to be corrected in accordance with the correction equations out-lined in the discussion with regard to the diagram of Fig. 5.
As noted in the discussion of making elevation and azimuth correction for the borehole, rotation of the sub-surface instrument about its longitudinal axis will affect the readings obtained by the X-axis and Y-axis sensors.
Practically speaking, the apparatus can rotate without restriction, or it can be partially restricted from free rotation by using standoffs. The standoffs would comprise four rubber bars equally spaced around the circumference of the housing to restrict rotary motion until the tension in the cable can override the restraining influence of the bars. Rotation of the apparatus will generally not be excessive. However, the problem is greatly diminished by simultaneously sampling and retaining sensor outputs as is performed by the surface instruments.
On the basis of the elevation and azimuth correction angles, the drilling of the relief well is continued along a new path. After drilling has progressed an appropriate ~SS7354 distance which is not an extremely large distance with respect to the range of target as determined by the last `
survey, drilling is interrupted and the subsurface field sensing apparatus may again be lowered into the borehole to make a new survey to determine target range and direction.
If a near intercept of the target is made, the borehole may "
have to be plugged and partially redrilled to place the trajectory of the relief well borehole sufficeintly near the target. If redrilling is required, the new trajectory can be planned more accurately, with the new knowledge of the target well position.
Proper operation of the static field sensing system in the subsurface instrument to yield optimum accuracy depends upon precise orientation of the mechanical and magnetic axes of the four DC magnetometer sensor cores. As discussed earlier, each sensor has a cosine response pattern, and a three-dimensional visualization of this pattern would be of a pair of spheres joined together. The axis of maximum sensitivity is a line through the diameter of the spheres and the point of their contact. Also a null axis can be defined in a plane perpendicular to the axis of maximum sensitivity and containing the point of contact of the spheres. Although rotation about the axis of maximum sensi-tivity theoretically will not affect the sensor reponse, if ` the mechanical and magnetic axes do not correspond, then the sensor's axis of maximum sensitivity will define a cone as the sensor is turned about its mechanical axis. Accordingly, variations in the magnetic field being detected will also result. The amount of misalignment of this type can be determined and appropriate correction factors can be applied to the raw data supplied by the sensors.

lt~S'~3S4 In addition to the problem of axis misalignment in the individual sensors, there is also the problem of maintaining the sensors at a mutually perpendicular disposition. To correct for this problem, the four sensors should be mechan-ically aligned as closely as possible, with the misalignment being measured in terms of its response output when placed in precisely defined magnetic fields. Correction factors are also determined for this type of misalignment, which correction factors are applied to the raw data obtained from the subsurface instrument. -A final problem involves adjusting the axial magnetic sensors of the subsurface apparatus to have their magnetic axes coincide with the centerline axis of the cylindrical -outer housing. The most convenient solution to this problem is to carefully align the mechanical axis of the axial magnetic sensors with the housing and rely on the correction factor mentioned above that corrects for sensor magnetic axis misalignment with respect to the mechanical axis of the ,' sensor.
~ 20 Although no techniques have been described in detail :1 .
for carrying out the calculations for target range and target direction determination, anyone skilled in the com-. . .
puter art can program a computer to solve the equations provided herein and to apply the techniques of vector anal-ysis to the acquired data. Although the calulations may be carried out by a hand-held calculator such as an HP-65, a calculator such as a Hewlett-Packard 9815A is preferred.
Programs for either instrument may be formulated from the manuals accompanying those instruments.
The foregoing description of the invcntion has been directed to a particular preferred embodiment of the present invention for purposes of explanation and illustration. It will be apparent, however, to those skilled in this art that - -many modifications and changes in the apparatus and method may be made without departing from the scope and spirit of the invention. It is, therefore, intended that the fol-lowing claims cover all equivalent modifications and varia-tions as fall within the scope of the invention as defined by the claims.

Claims (50)

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:
1. A method of directional subsurface drilling of a first borehole to intersect a second well containing a ferromagnetic target, comprising the steps of:
measuring the components of the earth's magnetic field along orthogonal axes at a first location in the first borehole sufficiently remote from the target to be unaffected by any magnetic field of the target;
measuring components of the total magnetic field along orthogonal axes at a second location in the first borehole sufficiently proximate the target to detect the magnetic field of the target superimposed upon the earth's field;
determining the direction of the superimposed magnetic field of the target from the second location using the measurements of the components of the earth's magnetic field;
measuring the component of the total field in the direction of the axis of the first borehole at a plurality of locations in the first borehole to determine the gradient of the target field in the direction of the axis of the first borehole;
determining the range of the target from one of said plurality of locations using the measurements of the component of the total field in the direction of the axis of the first borehole; and orienting the direction of drilling of the first borehole in the direction of the target magnetic field from a position in the first borehole from which the second well may be conveniently intercepted based upon the target range and direction determinations.
2. The method of Claim 1 wherein the measurements of the component of total magnetic field intensity in the direction of the axis of the first borehole are made by two aligned magnetic field sensors spaced apart by a predetermined separation, .DELTA.r.
3. The method of Claim 1 wherein the determination of the direction of the adjacent well involves measuring three magnetic field components, and resolving the components into a resultant vector indicative of the direction to the adjacent well.
4. The method of Claim 1 including the steps of:
interrupting the drilling of the first borehole;
redetermining direction and range of the target from a third location in the first borehole;
reorienting the course of drilling of the off-vertical relief well borehole; and periodically repeating the steps in sequence until the first borehole intersects the second well.
5. The method of Claim 1 wherein the step of orienting the course of drilling involves the determination of an azimuth correction angle and an elevation correction angle using the difference in the component measurements along orthogonal axes of the total field at said second location and the measured components of the earth's magnetic field.
6. The method of Claim 1 wherein the measurements of the component of total magnetic field intensity in the direction of the axis of the first borehole are made at more than two locations of predetermined separation along the axis of the first borehole; and the determination of target magnetic field intensity gradient is made over each separation between adjacent pairs of locations by forming a ratio (.DELTA.H/.DELTA.r) of the difference in adjacent measurements of total magnetic field intensity component in the direction of the axis of the borehole, .DELTA.H, to the predetermined separation, .DELTA.r.
7. The method of Claim 6 wherein the determination of range involves:
determining an average value of the component of target magnetic field intensity in the direction of the axis of the first borehole for each separation using adjacent pairs of measurements;
forming ratios of average target magnetic field intensity component, H, in the direction of the axis of the first borehole to target magnetic field intensity gradient, .DELTA.H/.DELTA.r, in the direction of the axis of the borehole using corresponding measurements for each separation;

substituting the ratios for adjacent separations in the equation where H1 is the value of H over a first separation, H2 is the value of H over a second, adjacent separation, .DELTA.H1/.DELTA.r is the gradient .DELTA.H/.DELTA.r over the first separation, .DELTA.H2/.DELTA.r is the gradient .DELTA.H/.DELTA.r over the second, adjacent separation, r1 is the range to the target from the first separation, r2 is the range to the target from the second, adjacent separation; and determining from the equation the value of the range, r.
8. A method of directional subsurface drilling of an off-vertical relief well borehole to intersect an adjacent well having remanent magnetization, comprising the steps of:
running magnetic field sensing apparatus into the relief well borehole, stopping at a location therein sufficiently far from the adjacent well that the magnetic field existing about the well is not substantially detected and measuring components of the earth's magnetic field along three mutually perpendicular axes;
determining relief well borehole azimuth and slope angles with reference to the earth's magnetic field;
lowering said magnetic field sensing apparatus and simultaneously measuring components of the total magnetic field along three mutually perpendicular axes at a plurality of spaced locations of defined separation-along the relief well borehole, with one of the measured components being that which is in the direction of the relief well borehole;
determining the direction to the adjacent well by measuring three components of the total magnetic field, subtracting the measured component values of the earth's field and resolving the remaining quantities of the components into a resultant vector;
determining the gradient of the remanent magnetic field intensity in the direction of the relief well borehole over defined portions of the relief well;
determining the range from a location along the relief well borehole to the adjacent well using the measurements of the component total magnetic field intensity in the direction of the relief well borehole and the gradient of the remanent magnetic field intensity in the direction of the relief well borehole; and orienting the course of drilling of the off-vertical relief well borehole based upon the range and direction of the adjacent well from the relief well borehole.
9. The method of Claim 8 wherein the step of determining borehole azimuth and slope involves measuring components of the earth's magnetic field to determine borehole orientation with respect to the dip and direction of the earth's magnetic field.
10. The method of Claim 8 wherein the step of determining range to the adjacent well involves;
determining an average value (H) of remanent magnetic field intensity component in the direction of the relief borehole for each separation between adjacent measurement locations, said average magnetic field intensity component being determined using adjacent pairs of measure-ments;
determining an average magnetic field intensity gradient (.DELTA.H/.DELTA.r) for the remanent field in the direction of the relief borehole for each separation between adjacent measurement locations, said average magnetic intensity gradient being determined by dividing the difference in magnitude between adjacent pairs of remanent magnetic field intensity components by the separation between the adjacent locations at which the intensity measurements are made; and forming ratios of average magnetic field intensity of the remanent field component in the direction of the relief borehole to average remanent magnetic field intensity gradient using the values of each determined for respective corresponding separations.
11. The method of Claim 10 further involving:

(a) substituting the ratios into the equation where is the gradient, r is the range, and n is the fall-off rate of intensity with distance;
(b) approximating a value of n; and (c) determining the range, r, to the adjacent well.
12. A method of surveying the range to a subterranean body having remanent magnetization from an adjacent borehole comprising the steps of:
measuring the component of the total existing magnetic field in the direction of the borehole at a plurality of locations along the borehole;
determining the gradient of the magnetic field emanating from the subterranean body in the direction of the borehole;
and determining the range of the subterranean body from one of said plurality of locations along the borehole using the gradient determination and the measured component of the magnetic field.
13. The method of Claim 12 wherein the measurements of the component of total magnetic field intensity in the direction of the borehole are made at locations of predetermined separation along the axis of the borehole;
and the determination of the gradient of the intensity of the magnetic field of the subterranean body is made as separate determinations over each separation between adjacent pairs of locations by forming a ratio (.DELTA.H/.DELTA.r) of the difference in adjacent measurements of total magnetic field intensity component in the direction of the borehole to the predetermined separation, .DELTA.r.
14. The method of Claim 13 wherein the determination of range involves:
determining an average value of the component of target magnetic field intensity in the direction of the borehole for each separation using adjacent pairs of measurements;
forming ratios of average target magnetic field intensity component, H, in the direction of the borehole to target magnetic field intensity gradient, .DELTA.H/.DELTA.r, in the direction of the axis of the borehole using corresponding measurements for each separation;

substituting the ratios for adjacent separations in the equation where H1 is the value of H over a first separation, H2 is the value of H over a second, adjacent separation, .DELTA.H1/.DELTA.r is the gradient .DELTA.H/.DELTA.r over the first separation, .DELTA.H2/.DELTA.r is the gradient .DELTA.H/.DELTA.r over the second, adjacent separation, r1 is the range to the target from the first separation, r2 is the range to the target from the second, adjacent separation; and determining from the equation the value of the range, r.
15. The method of Claim 14 wherein the measurements of the component of total magnetic field intensity in the direction of the axis of the borehole are made by two aligned magnetic field sensors spaced apart by a predetermined separation, .DELTA.r.
16. A method of directional subsurface surveying from a borehole to locate a subterranean ferromagnetic target, comprising the steps of:
measuring the components of the earth's magnetic field along orthogonal axes at a first location in the borehole sufficiently remote from the target to be unaffect-ed by any magnetic field of the target;
measuring components of the total magnetic field along orthogonal axes at a second location in the borehole sufficiently proximate the target to detect the magnetic field of the target superimposed upon the earth's field;
determining the direction of the superimposed magnetic field of the target from the second location using the measurements of the components of the total magnetic field and the measurements of the components of the earth's magnetic field;
measuring the component of the total field in the direction of the axis of the borehole at a plurality of locations in the borehole to determine the gradient of the target field in the direction of the axis of the borehole;
and determining the range of the target from one of said plurality of locations using the measurements of the component of the total field in the direction of the axis of the first borehole.
17. The method of Claim 16 wherein the measurements of the component of total magnetic field intensity in the direction of the axis of the borehole are made by two aligned magnetic field sensors spaced apart by a predetermined separation, .DELTA.r.
18. The method of Claim 16 wherein the determin-ation of the direction to the target involves measuring three magnetic field components, and resolving the components into a resultant vector indicative of the direction to the adjacent well.
19. The method of Claim 16 wherein the measurements of the component of total magnetic field intensity in the direction of the axis of the borehole are made at more than two locations of predetermined separation along the axis of the borehole; and the determination of target magnetic field intensity gradient is made over each separation between adjacent pairs of locations by forming a ratio (.DELTA.H/.DELTA.r) of the difference in adjacent measurements of total magnetic field intensity component in the direction of the axis of the borehole to the predetermined separation, .DELTA.r.
20. The method of Claim 19 wherein the deter-mination of range involves:
determining an average value of the component of target magnetic field intensity in the direction of the axis of the borehole for each separation using adjacent pairs of measurements;
forming ratios of average target magnetic field intensity component, H, in the direction of the axis of the borehole to target magnetic field intensity gradient, .DELTA.H/.DELTA.r, in the direction of the axis of the borehole using corresponding measurements for each separation;

substituting the ratios for adjacent separations in the equation where H1 is the value of H over a first separation, H2 is the value of H over a second, adjacent separation, .DELTA.H1/.DELTA.r is the gradient .DELTA.H/.DELTA.r over the first separation, .DELTA.H2/.DELTA.r is the gradient .DELTA.H/.DELTA.r over the second, adjacent separation, r1 is the range to the target from the first separation, r2 is the range to the target from the second, adjacent separation; and determining from the equation the value of the range, r.
21. A directional subsurface surveying from a borehole to locate a subterranean ferromagnetic target, comprising the steps of:
measuring the components of the earth's magnetic field along orthogonal axes at a first location in the borehole sufficiently remote from the target to be unaffected by any magnetic field of the target;
measuring components of the total magnetic field along orthogonal axes at a second location in the borehole sufficiently proximate the target to detect the magnetic field of the target superimposed upon the earth's field;
determining the direction of the superimposed magnetic field of the target from the second location using the measurements of the components of the total magnetic field and the measurements of the earth's magnetic field;

measuring one component of the total field at a plurality of locations along the borehole to determine the rate of change of the target field with distance down the borehole; and determining the range of the target from one of said plurality of locations using the measurements of the component of the total field in the direction of the axis of the first borehole.
22. The method of Claim 21 wherein the determina-tion of the direction to the target involves measuring three magnetic field components, and resolving the components into a resultant vector indicative of the direction to the adjacent well.
23. The method of Claim 21 wherein the measurements of the component of total magnetic field intensity are made at more than two locations of predetermined separation along the axis of the borehole; and the determination of target magnetic field intensity gradient is made over each separation between adjacent pairs of locations by forming a ratio (.DELTA.H/66r) of the difference in adjacent measurements of total magnetic field intensity component to the predeter-mined separation, .DELTA.r.
24. The method of Claim 23 wherein the determina-tion of range involves:
determining an average value of the component of target magnetic field intensity for each separation using adjacent pairs of measurements;
forming ratios of average target magnetic field intensity component, H, to target magnetic field intensity gradient, .DELTA.H/.DELTA.r, using corresponding measurements for each separation;

substituting the ratios for adjacent separations in the equation where H1 is the value of H over a first separation, H2 is the value of H over a second, adjacent separation, .DELTA.H1/.DELTA.r is the gradient AH/.DELTA.r over the first separation, .DELTA.H2/.DELTA.r is the gradient AH/.DELTA.r over the second, adjacent separation, r1 is the range to the target from the first separation, r2 is the range to the target from the second, adjacent separation; and determining from the equation the value of the range, r.
25. A magnetic field sensing apparatus for disposition in a borehole to locate a subterranean magnetic body exhibiting a static magnetic field, comprising:
an outer housing or non-magnetic material;
a pair of mutually perpendicular radially oriented magnetic field sensors disposed within said housing;
a pair of aligned axial magnetic field sensors spaced apart a predetermined separation within said housing and oriented perpendicular to said radial magnetic sensors;
said axial and radial magnetic sensors measuring components of the magnetic field along orthogonal axes.
26. The apparatus of Claim 25 wherein the field sensing apparatus further comprises a vertical sensor disposed within said housing for indicating the degree of rotation of said housing about its longitudinal centerline axis.
27. The apparatus of Claim 25 wherein the field sensing apparatus further comprises a voltage regulator circuit disposed within said housing for receiving unregulated power and supplying regulated power to said magnetic field sensors.
28. The apparatus of Claim 25 wherein said housing comprises:
an elongate cylindrical sleeve;
a nose cone secured to the forward end of said sleeve; and a multi-conductor connector secured to the rear of said sleeve.
29. The apparatus of Claim 28 wherein said axial magnetic sensors and said radial magnetic sensors are mounted on a frame having four elongate stringers extending between said connector and the forward end of said sleeve proximate the nose cone.
30. The apparatus of Claim 25 wherein said radial and axial magnetic field sensors exhibit a cosine response.
31. The apparatus of Claim 30 wherein each of said magnetic field sensors comprises:
a magnetic sensor core element;
a core driver circuit providing a driving current to said core element;

a detector circuit for receiving an output signal from said core element;
a servo-driver circuit coupled to said detector circuit through null balancing means;
a feedback line from the output of said servo-driver to said core element;
said null balancing means being operable through said feedback line to reduce error in the output of said sensor element; and an output amplifier coupled to the servo-driver circuit.
32. The apparatus of Claim 31 wherein said core driver circuit provides a clipped sine wave waveform to said core element.
33. The apparatus of Claim 31 further comprising an oscillator circuit connected to the core driver circuit of each magnetic field sensor.
34. The apparatus of Claim 33 wherein said core driver circuit comprises:
an amplifier circuit having an input terminal that is accoupled to the output terminal of the oscillator circuit, said amplifier having a gain greater than unity;
and a push-pull emitter follower current amplifier ac-coupled to said amplifier circuit comprising first and second transistors.
35. The apparatus of Claim 33 wherein said magnetic sensor core element comprises:
a toroid forming a primary winding;
a bobbin of ferromagnetic material having an opening therein for receiving said toroid; and a coil of wire wound about said bobbin to form a secondary winding.
36. The apparatus of Claim 33 wherein said detector circuit comprises:
a push-pull emitter follower circuit having first and second transistors; and said null balancing means comprises a potentio-meter operably connected to the emitters of said first and second transistors.
37. The apparatus of Claim 33 wherein said servo-driver circuit comprises:
an amplifier having first and second input terminals, and an output terminal;
first and second transistors arranged in a Darlington amplifier configuration with the base lead of said first transistor being coupled to the output terminal of said amplifier;
said feedback line connecting to the junction formed by the collector of said first transistor and the emitter of said second transistor and comprising variable resistance means; and a network for setting the gain of said amplifier connecting between the collector of said first transistor and an input terminal of said amplifier.
38. The apparatus of Claim 33 wherein said output amplifier comprises:
a gain potentiometer having a first leg connected to said servo-driver, a second leg connected to a supply of electrical power, and a wiper;

an amplifier having a first input lead connected to the wiper of said gain potentiometer, a second input lead and an output terminal;
a push-pull emitter follower circuit connected to the output terminal of said amplifier comprising first and second transistors; and a network for setting the gain of said amplifier connecting between the junction of the emitters of the transistors and the second input lead of said amplifier.
39. In a magnetic field sensing apparatus suitable for disposition in a subterranean borehole to perform a survey of the range to a subterranean ferromagnetic target body exhibiting a magnetic field, the improvement comprising:
first and second magnetic field sensors spaced apart by a predetermined separation and oriented to have their axes of maximum sensitivity substantially aligned with one another and disposed substantially parallel with the axis of the borehole.
40. The apparatus of Claim 39 wherein said first and second magnetic field sensors exhibit a cosine response When rotated about an axis of rotation that is perpendicular to the axis of maximum sensitivity.
41. The apparatus of Claim 39 wherein each of said first and second magnetic field sensors comprises:
a magnetic sensor core element;
a core driver circuit providing a driving current to said core element;
a detector circuit for receiving an output signal from said core element;

a servo-driver circuit coupled to said detector circuit through null balancing means;
a feedback line from the output of said servo-driver to said core element;
said null balancing means being operable through said feedback line to reduce error in the output of said sensor element; and an output amplifier coupled to the servo-driver circuit.
42. A survey system for determining the range and direction to a subterranean ferromagnetic body exhibiting a magnetic field from a location within an adjacent subterranean borehole; which comprises:
subsurface magnetic field sensing apparatus for disposition in the adjacent borehole, said apparatus having magnetic sensors for measuring components of a magnetic field along orthogonal axes including a pair of aligned magnetic sensors oriented to make measurements of a component of the magnetic field in the direction of the borehole; and surface instrumentation operably coupled to said subsurface magnetic field sensing apparatus for determining range and direction from said apparatus to the subterranean body.
43. The system of Claim 42 wherein said surface instrumentation comprises:
an analog-to-digital converter for digitizing the measurements made by said magnetic sensors;
an interface for converting the format of the digitized to a different format;

a calculator for receiving the converted digitized data and determining the range and direction; and display means for presenting the range and direction determinations.
44. The system of Claim 42 further comprising:
a digital multiplexer connected between said analog-to-digital converter and said interface for taking multi channel digital data and placing it onto a single data bus.
45. A magnetic field sensing apparatus for disposi-tion in a borehole to locate a subterranean ferromagnetic body exhibiting a time-varying magnetic field comprising:
a sensor for detecting a time-varying magnetic field of a predetermined frequency; and first and second static magnetic field sensors having axes of maximum sensitivity perpendicular to one another and perpendicular to the axis of the borehole, said first and second magnetic sensors being responsive to the earth's field.
46. The apparatus of Claim 45 wherein said time-varying magnetic field sensor comprises:
a parallel inductor and capacitor tuned to provide a maximum response when flux lines from said time varying magnetic field of predetermined frequency couples said inductor; and an amplifier coupled to said inductor and capacitor combination for increasing the level of a signal produced by said combination.
47. An apparatus for disposition in a borehole to locate a subterranean electro-conductive body exhibiting a time-varying electric field comprising:

an electric field potential probe for sensing the potential gradient of a time-varying electric field of a predetermined frequency;
a frequency selective amplifier coupled to said electric field potential probe; and first and second magnetic field sensors having axes of maximum sensitivity perpendicular to one another and perpendicular to the axis of the borehole, said sensors being responsive to the earth's field.
48. A method of directional subsurface surveying from a borehole to locate a subterranean ferromagnetic target, comprising the steps of:
a. establishing a time-varying magnetic field about said ferromagnetic target;
b. detecting said time-varying magnetic field at a plurality of locations in the borehole to measure the intensity of said field at the locations;
c. determining the intensity gradient of said time-varying field from the measurements of magnetic field intensity;
d. determining the range of the target from one of said plurality of locations using the field intensity measurements obtained in step b and the intensity gradient determined in step c; and e. determining the direction to the target from the detection of said time-varying magnetic field made in step b.
49. The method of Claim 48 wherein the measurements of the intensity of said time-varying magnetic field are made at more than two locations of predetermined separation along the axis of the borehole; and the determination of magnetic field intensity gradient is made over each separation between adjacent pairs of locations by forming a ratio (.DELTA.H/.DELTA.r) of the difference in adjacent measurements of magnetic field intensity to the predetermined separation, .DELTA.r.
50. The method of Claim 49 wherein the determination of range involves:
determining an average value of the magnetic field intensity for each separation using adjacent pairs of measurements;
forming ratios of average magnetic field intensity, H, to magnetic field intensity gradient, .DELTA.H/.DELTA.r, using corresponding measurements for each separation;
substituting the ratios Hs/.DELTA.Hs/.DELTA.r for adjacent separation in the equation ; and determining from the equation the value of the range, r.
CA275,893A 1976-05-12 1977-04-07 Surveying of subterranean magnetic bodies from adjacent off-vertical borehole Expired CA1057354A (en)

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HK11882A (en) 1982-03-19
NO147693B (en) 1983-02-14
US4072200A (en) 1978-02-07
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NL7704513A (en) 1977-11-15
FR2361671A1 (en) 1978-03-10
FR2361671B1 (en) 1982-07-23
DK166877A (en) 1977-11-13
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NO147693C (en) 1983-05-25
GB1585479A (en) 1981-03-04

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