The present invention generally relates to borehole logging and more particularly, to systems and methods for determining parameters of the motion of a logging tool in a borehole and compensating for this motion in the logging data.
Knowledge of the motion parameters of a logging tool relative to a borehole is important for obtaining accurate downhole measurement signals. Thus, for example, a shift in the sensitive volume of the logging tool caused by lateral motion of the tool relative to the borehole can distort the received signal and produce inaccurate measurements. Such distortions can be especially problematic in logging-while-drilling (LWD) and measurement-while-drilling (MWD) environments, where the tool itself is subjected to severe vibration. In some cases, the measurements may have to be completely discarded, as for example when a stick-slip condition occurs (where the drill bit stops rotating momentarily because of high friction and then rapidly accelerates when the moment exerted by the drill pipe exceeds the static friction). Clearly, it would be beneficial if the tool operator had access to information about the motions of the tool, so that measurements made during strong lateral and axial motions are discarded, or not even initiated.
Additionally, in many cases, it is important to select optimal activation times for the logging measurement and, if possible, to enable correction of the received signal based on the motion parameters of the logging tool. In such applications, it is necessary to accurately determine the lateral tool velocity of the tool in real time.
In the simplest system for measuring the lateral tool velocity relative to a borehole, two mutually orthogonal accelerometers can be placed on the tool axis, such that they are sensitive to the lateral acceleration. However, such placement is generally not possible in downhole tools because of design constraints, in particular owing to the need to have an open space within the center of the tool for a mud flow channel.
As such, in prior art systems for determining the lateral velocity of a drilling tool, two pairs of accelerometers are attached to diametrically opposite sides of the tool, usually near the surface of the tool. See, for example, co-pending U.S. Pat. No. 6,268,726, assigned to the assignee of the present application. This application is incorporated herein by reference for all purposes. The accelerometers together provide radial acceleration components, ar1 and ar2, and tangential acceleration components, at1 and at2, of the tool. Since the accelerometers rotate with the tool, their measurements are in the reference frame of the rotating tool, i.e., the rotating frame. Given their opposite placement, the accelerometer pairs register equal but opposite accelerations due to lateral tool motion and equal radial (centrifugal) as well as angular accelerations due to tool rotation. The radial and tangential forces due to tool rotation are compensated for the opposite accelerations by subtracting the reading of one accelerometer from the reading of the diametrically opposite one (ar2 is subtracted from ar1 and at2 is subtracted from at1). The remaining signal is twice the actual lateral tool acceleration in the directions of ar1 and at1, respectively, as seen in the rotating frame. The acceleration components compensated for the centrifugal and angular accelerations are therefore given by the expressions:
ar=(ar1−ar2)/2, for the radial tool acceleration; and
at=(at1−at2)/2, for the tangential tool acceleration.
The lateral velocity is calculated by integrating the above acceleration components. There are two main problems associated with this prior art approach. First, the signal measured by the accelerometers will also contain a gravitational component if the tool orientation is not vertical. The magnitude of the gravitational component is Gsinα, where α is the angle of tool inclination relative to vertical and G is the gravitational acceleration constant. The frequency of the gravitational component is related to the tool rotation. Tool tilt away from vertical is sensed by the accelerometers and, thus, introduces an inaccuracy in the lateral tool acceleration readings.
Commonly, the gravitational acceleration component is removed from the signal by employing a high pass filter. The filter cut-off frequency is set to separate frequencies of the gravitational component modulated by the tool's rotation from the higher frequencies assumed to be caused by the tool's lateral motion. This technique, however, is not effective if the tool's rotational rate is high or not constant, for example, in a stick-slip situation, gravitational acceleration components are generated within the band of those related to the tool's lateral motion.
The second problem occurs because the accelerometers, which are placed on the tool, measure the tool's lateral velocity in the tool frame of reference rather than the desired borehole frame of reference.
With reference to
Obtaining accurate lateral tool velocity is important to ensure that the accuracy of NMR porosity measurements does not degrade by more than about 5%. For example, the lateral displacement of the tool's center of gravity should be limited to about 0.1 mm relative to the borehole within a measuring time frame of 500 μseconds. In practice, it is desirable that the lateral tool velocity should not exceed 0.2 m/sec during a typical NMR reading. Tool displacements greater than about 0.25 mm may introduce a system error associated with phase shift of the NMR echo. In addition to systemic error, the signal-to-noise may also degrade.
Therefore, there is a need to provide a system and method for accurately determining the lateral tool velocity and overcoming the deficiencies associated with the prior art. By knowing the tool's velocity, the NMR signal may be corrected. Additionally, along with velocity information, an uncertainty estimator can be calculated to provide confidence levels of the measurements.
The present invention is directed to a system and method for providing lateral tool velocity measurements corrected for a gravitational acceleration component, and for lateral velocity measurements in the borehole frame of reference. The invention allows correction of either one independently.
The system of the present invention comprises two pairs of accelerometers, a pair placed on opposite radial sides of the tool's rotational axis. Each of the two pairs of accelerometers detects both radial and tangential tool acceleration components. The system further comprises: two magnetometers placed orthogonally with respect to each other to detect the tool's magnetic phase (also called magnetic tool face); means for sampling the accelerometer and magnetometer signals; and means for real time processing and calculation of the corrected lateral tool velocity.
The method of the present invention includes: concurrently obtaining the tool's instantaneous radial and tangential accelerometer data as well as the tool's instantaneous magnetic phase data; determining the tool's gravitational phase data, and using this data to provide a corrected lateral tool velocity.
Accordingly, in one aspect, the invention is an apparatus for making borehole measurements using a logging tool, comprising: at least two accelerometers measuring motion parameters of the tool in a borehole, the motion parameters being measured in a tool reference frame; two or more magnetic induction sensors measuring magnetic induction dependent on the orientation of said accelerometers in relation to the gravitational field; and a processor computing the motion parameters of the tool in a borehole reference frame by taking into account the orientation of said accelerometers in relation to the gravitational field.
In another aspect, the invention is a method for making borehole measurements with a logging tool moving along a borehole subjected to a gravitational field, comprising: (a) measuring motion parameters of the tool in a tool reference frame; (b) estimating components of the measured motion parameters due to the gravitational field in the borehole; (c) computing a set of corrected motion parameters, the step of computing comprising removing the estimated components due to the gravitational field; and (d) providing at least one measurement along the borehole with the logging tool, said at least one measurement taking into account the computed set of corrected motion parameters.
The present invention is best understood with reference to the attached drawings, in which:
The structure and function of the preferred embodiment can best be understood by reference to the attached drawings. Where the same reference numerals appear in multiple figures, the numerals refer to the same or corresponding structure in those figures.
A. The System of the Invention
In a preferred embodiment, the system of the present invention for determining the lateral velocity of a drilling tool comprises at least two pairs of accelerometers placed opposite each other across the tool axis of rotation, a first and second magnetometer placed on the tool to provide detection of the tool's rotational magnetic phase relative to the earth's gravitational field, an interface for reading signals from the accelerometers and magnetometers, and a data processor for providing a corrected value of lateral tool velocity in the borehole frame of reference.
As shown in
Examples of equipment that can be used in accordance with the present invention include the digital signal processor model ADSP21060 SHARC chip from Analog Devices, which possesses a six channel A/D converter to accommodate acceleration and magnetic signals, micro-machined silicone accelerometers from Silicon Designs with a bandwidth of 5 kHz and magnetoresistive sensors (magnetometers) from Honeywell (Model HMC1002). Also included in a preferred embodiment of the system are communication channels (not shown) to control the digital processor and to retrieve real time velocity information, and a digital synchronization line to trigger the NMR measurements when the instantaneous lateral tool velocity is low.
Referring to FIG. 1B and
Additional parts of the tool of the drilling system are depicted in
B. The Method of the Invention
In accordance with the preferred embodiment, the method of the invention permits two independent corrections. The first correction removes the gravitational component from the acceleration readings that results when the tool is tilted away from the vertical direction. The second correction provides the lateral velocity of the drilling tool relative to a borehole reference frame.
In a preferred embodiment, the method which corrects both inaccuracies includes the following steps (discussed again in greater detail later):
In accordance with the present invention, the signals recorded by the accelerometers are related to other system variables by the following expressions:
where:
The tool phase φ is:
where ω is the instantaneous angular speed of the tool. From previous equations for ar1 and ar2 the module of ω is calculated as
and the angular acceleration is
Employing the above relationships, and the described hardware system and programming software, the method for obtaining lateral tool velocity with correction for the gravitational component and conversion of the velocity relative to a borehole reference frame is now discussed in detail. The method includes the following particular steps.
In a preferred embodiment, this step requires reading real-time data signals from the two (or more) accelerometers and two magnetometers to obtain the parameters ar1, ar2, at1, at2, Bx and By. Parameters Bx and By are orthogonal magnetic phase readings relative to the earth's magnetic field.
The magnetic phase readings are used to determine the tool's magnetic phase with respect to the earth's gravitational pull. The direction of the magnetic field in space however, does not directly coincide with the gravitational pull; there is a phase difference (phase shift) of φo. In most conditions, where the magnetic field disturbance is not strong and the borehole has a relatively constant direction, the phase shift φo will be a constant within the time frame of the few seconds necessary to determine the tool velocity. Therefore, the relationship φ=φm+φo where φo=a constant, can be reasonably assumed. Knowing Bx and By, the tool's magnetic rotation phase φm maybe obtained according to the present invention using the expressions:
Bx=B sin(αm)cos(φm)
By=−B sin(αm)sin(φm) (5)
where B is the amplitude of the magnetic induction signal, and αm is the angle between the tool's axis and the earth's magnetic field vector.
The tool magnetic phase φm is determined directly from (5) provided that the borehole direction does not coincide with the direction of the B vector such that the noise level of the magnetic measurements is comparable to the signals Bx and By. Knowing Bx and By, the tool's magnetic rotation phase φm may be obtained by using the function φ=atan2(By,Bx) common to most mathematical function libraries. The function atan2 resolves all four quadrants of the full angle (360 degrees).
If a correction for tool tilt is not desired, then it is unnecessary to determine Gsin(αi) in this step. However, it is the usual case to correct for the effect of tool tilt. The following procedure is used in a preferred embodiment to determine Gsin(αi) and φo, where G is the acceleration constant of earth's gravitational field (≅9.81 m/s2). The tool magnetic phase φm is known from the previous step. Gsin(αi) can be calculated under the assumption that the gravitational component does not contribute to the lateral acceleration of the tool.
As shown in
The signals are then decimated and fed into a quadrature detector known to those skilled in the art. In the quadrature detector both acceleration signals ar and at are multiplied by the sin(φm) and cos(φm). The outputs averaged over time (few seconds in a preferred embodiment) yield two complex numbers c and d, where:
Where: N is the number of signal samples processed during the averaging;
Both complex numbers are 90 degrees out of phase since the gravitational component is 90 degrees out of phase in ar and at respectively. The magnitude of these complex numbers equals to 0.5 Gsin(αi) and the phase of c equals to φo, therefore:
G sin(αi)=2√{square root over (creal2+cimag2)}
φ0=α tan2(cimag,creal)
Once the phase shift φo is found from step (d), combined with the parameter φm known from the previous step, φ may be calculated according to the relationship:
φ=φm+φo
The same information can be obtained from the complex number d, remembering that there is a 90 degree phase shift between c and d. If the magnitude and phase is obtained from both complex outputs, in a preferred embodiment it can be averaged to decrease uncertainty.
This process yields both the phase shift φo and magnitude of the gravitational component Gsin(αi). The time constants of the averaging process can be as long as 30 seconds or more, if the phase information from magnetic sensors is used, since there is no systematic drift between the φm and φo other than changes of the borehole direction or of the magnetic field, which typically are very slow.
To assess the quality of the real-time data, the standard deviation of each measured/calculated quantity may be determined, if possible. If the same information is available from several sources, preferably the one with the lowest standard deviation is chosen. Based on individual uncertainty estimates, the uncertainty of velocity determination can be calculated and made available to the computer system for storage.
While phase detection is desirably obtained by using magnetometers, this method is not available when the tool axis coincides with the magnetic vector. An alternative, although less accurate method of phase determination using the accelerometer signals, is available in accordance with a specific embodiment of the present invention. According to Eq. (2), the gravitational tool phase φ can be calculated as an integral of the instantaneous angular velocity ω, which can be determined from Eq. (3) and Eq. (4). It will be appreciated that this approach is sensitive to accelerometer scale error and may suffer from poor resolution of ω at low speeds. Nonetheless, in accordance with the invention, the approach can serve as a backup algorithm in situations where magnetic information is not available.
To obtain lateral accelerations ax and ay, the raw acceleration signals are subtracted so that centrifugal and angular acceleration components cancel out:
The signals above also contain the modulated gravitational component Gsin(αi)cos(φ). Since Gsin(αi) and φ have been determined in the previous step, in accordance with the present invention the gravitational component can be subtracted from both signals yielding accelerations corrected for gravitational components arg and atg:
ax cos(φ)−ay sin(φ)=arg
ax sin(φ)+ay cos(φ)=atg (8)
Equation (9) is used to convert the tool acceleration from the (r-t-a) reference frame to the XYZ borehole reference frame. All variables have been previously determined in order to calculate ax and ay. Note also that Eq. (9) may be used when no correction is desired for the gravity effect of tool tilt on the accelerometers, and only a conversion to the borehole frame of reference is desired.
Knowing ax and ay from the previous step, the lateral velocity components vx and vy may be calculated. The lateral velocity calculation is provided in a preferred embodiment as follows:
where vox and voy are unknown initial velocities at arbitrarily chosen time To. Since the borehole restrains the motion of the tool during any period, the lateral displacement is less than or equal to the slack Δs between the drill collar and the borehole wall.
Since values of ax and ay are known at any point in time, the initial velocities vox and voy can be calculated from:
with the uncertainty of the measurement method less than Δs/(d−To). For example, to achieve an uncertainty of 0.02 m/s in a borehole having a slack of 5 cm, the minimum integrating time should be 2.5 seconds.
After the individual lateral velocity components are extracted, the modulus of the lateral velocity is calculated in accordance with the invention as:
v=√{square root over (vx2+vx2)} (12)
Once the instantaneous velocity is calculated, the decision can be made whether to initiate an NMR measurement.
In order to use the velocity calculation as described by equations (10-12) with computer processing, it is desirable to simplify the data processing to minimize the calculations. Thus, assuming a minimum To of 2.5 seconds and a sampling frequency of 8 kHz, the number of samples integrated would exceed 20,000. The memory requirement for direct implementation would be substantial. Therefore, in a preferred embodiment, a multiple-window approach is performed, wherein the integrals are calculated over K partially overlapping time windows as shown in FIG. 5. The individual samples do not have to be stored, only the integrals and number of samples integrated. When an integrator reaches the preset number of samples, i.e., 2.5 seconds worth of data in a specific embodiment, it becomes the source of velocity information for the system, until the next-in-line integrator reaches the minimum number of samples. Then the first integrator is reset and begins another new integration, while the second integrator provides velocity information. This processing approach tolerates some discontinuity in the velocity signal that is introduced when switching integrators in the Kth increase during processing. However, as simplified using the above approach the calculations are manageable and provide reasonably accurate results. The performance of recursive filters during velocity retrieval may also be tested in a specific embodiment.
C. Typical Acceleration Signals Provided in the Tool Reference Frame and System Bandwith Concerns
A data set obtained from J. Dudley's, “MRIL MWD Sensor Physics” DNMWD016 Rev.1a, Security DBS, was analyzed to assess the magnitude and spectral composition of typical lateral tool accelerations. This reference provides graphs of a complete data set in the reference frame of the rotating tool (drill bit), and is hereby incorporated by reference. The following example data analysis focuses only on the radial component of the tool acceleration and only for selected fragments. No calibration information is provided.
The centrifugal acceleration depends on the radius and angular velocity of the tool. The accelerometer's operating radius is limited by the tool's diameter. The average angular velocity of the tool equals the driving velocity. However, under stick-slip situations, the instantaneous velocity may change quite rapidly.
The natural frequency of the tool string and forces on the bit modulate the instantaneous angular velocity of the tool. Even during relatively vibration-free periods, ω tends to oscillate, as illustrated in FIG. 6. The angular velocity modulation is much more dramatic in stick-slip conditions, where the drill bit actually stops rotating for fractions of a second. From a momentary standstill, the bit accelerates when the moment exerted by the winding drill pipe exceeds the static friction. The peak angular velocity under stick-slip conditions is more than twice the average velocity.
The acceleration data provided by Sperry-Sun in a report by J. D. Jansen, “Whirl and Chaotic Motion of Stabilized Drill Collars” SPE 20930, pp. 435-448, are in the rotating tool reference frame. The reference is hereby incorporated by reference.
The frequency spectrum in
Since the lateral motion of the tool can be described in the frequency domain as a sum of harmonic motions of various frequencies, it is possible to determine the low frequency cutoff of the measurement system based on a desired velocity accuracy, and a maximum allowable amplitude of the tool's movement which is limited by the borehole walls. See Table 1. For example, for a typical 2 cm or 4 cm peak-peak amplitude limitation, the system must pass accelerations down to 0.2 Hz in order to achieve a precision of 0.025 m/s. The peak acceleration in that case would be approximately 3 mG, this value giving an indication of the required maximum resolution of the accelerometer at the lowest frequencies.
The above estimate is only valid for a system that does not rotate. If the tool rotates with constant ωo, then the acceleration induced by the slow lateral motion ω would be modulated as the rotational signal shifts ωo−ω and ωo+φ. However, there are conditions under which the tool stops rotating while performing measurements.
Table 2 above shows the peak accelerations observed during harmonic lateral motion. For example, to observe 50 G acceleration, the tool must vibrate at a frequency of 50 Hz with an amplitude of 5 mm or 10 mm peak-peak.
The strongest accelerations were observed during bit whirl. Peak values of about 13-14 G were detected in Dudley's sample accelerations. As shown in
Close et al., IADC/SPE 17273, pp. 559-568, conducted measurements of Borehole Assembly (BHA) vibration while drilling using a sampling rate of 2 kHz. The reference is incorporated herein by reference. The analysis revealed peak lateral accelerations of 13 G during reaming, 2 G behind the positive displacement downhole motor, and 25 G while drilling through casing shoe. Accelerations in excess of 100 G were also reported when the BHA rotational speed matched the BHA's lateral resonant frequency. Accelerations of that magnitude are frequently destructive.
From published data it is apparent that shocks in excess of 50 G are rare and are not considered within normal operating conditions. Therefore, the accuracy of a motion detection system under these infrequent conditions is not critical. However, the system should be able to recover from such severe shocks without lasting adverse effects.
To estimate the acceleration magnitude and shape during collision of the tool with a borehole, a simple model was used, simulating a section of the drill collar colliding with a perfectly rigid barrier. The elasticity K was approximated based on the drill collar size and the material property. The simulated acceleration at the pipe's center is shown in FIG. 12. The pulse duration is independent of the initial velocity and is affected only by the pipe's properties. As shown in
Estimates provided in Table 3 and
D. Uncertainty and Error Analysis
The accuracy of velocity calculations based on acceleration measurements are affected by both instrumental factors and motion characteristics. Some factors produce purely systematic errors, such as gain error, while others, despite their systematic character, are exhibited as semi-random errors owing to a randomizing effect of the conditions, for example, with bandwidth effect and quantization noise. Some factors, such as transducer noise are purely random. Owing to their dual nature, some uncertainty components may be described both statistically and as a worst case.
The effect of quantization noise can be approximated by a random noise with a variance of 1/12*q2, where q is the least square best fit value with a conversion resolution in m/s2. Since vx and vy are integrated over the period T containing T/dT samples, with dT the sampling interval, the variance of the velocity is:
The factor of ½ is a result of averaging the outputs of two accelerometers to obtain compensated acceleration signal (11). For a 14 bit+sign A/D converter and 50 G range, q is 0.03 m/s2. Assuming a T of 2.5 seconds and a dT of 125 μs, the variance of the individual velocity components is 1.17*10−8, resulting in a standard deviation of 0.00011 m/s. To simplify the calculations, the variance of total velocity v, as described by Eq. (14), can be estimated to be less than 2σ2Vx. The variance is proportional to velocity integration time and sampling interval and to the square of the A/D converter's resolution. Each additional bit reduces the standard deviation by a factor of 2.
The transducer noise σt can be transformed the same way as the quantization noise according to the expression:
except the input level is bandwidth dependent. Assuming a noise level of 1 mG/sqrt(Hz) using a Silicon Designs accelerometer having a bandwidth of 4 kHz, the input noise level can be estimated at 0.62 m/s2 rms. Applying Eq. (15) and multiplying the result by 2 yields a velocity variance of 0.00012 m2/s2 and a standard deviation of 0.011 m/s.
Any calibration error for the accelerometers will have a proportional effect on the calculated velocity. Since, over a long period of time, the average acceleration is zero, the effect of gain error is not cumulative. For any time period this error is proportional to the average acceleration for that time and the time duration. As a first approximation, the direct collision with the borehole wall may be analyzed. For the duration of the collision, the average acceleration is approximately 30 G and the pulse duration is 2.2 ms. The velocity error accumulated during the collision resulting from a 1% calibration error is 0.0065 m/s. The gain of the accelerometers can be initially calibrated to a measurement precision better than 0.5% using the earth's gravitational field as a reference.
Commercially available micro-machined silicone accelerometers have temperature coefficient of gain in the order of 2% over a 125° C. temperature span. This temperature behavior is repeatable so that compensation is possible. It is realistic to assume a net temperature coefficient after compensation to be less than 0.5%. Similarly, the resulting velocity error would be 0.0032 m/s.
The limited integration time results in an error dependent upon the degree of freedom the tool has in the borehole. The larger the borehole compared to the tool's diameter, the larger the error according to Eq. (11).
Any fluctuation of phase information used to compensate the gravitational field can cause a disturbance in the accelerometer information since the gravitational component is removed by subtracting the following term from equation (7):
Gcorr=G sin(αi) sin(φ) (16)
The sensitivity of this correction factor to phase noise is:
which peaks at Gsin(αi). Consequently, the variance of the acceleration signal due to the phase noise is:
σα2≈G2 sin2(αi)σφ2 (18)
Similarly as in Eq. (14) the resulting velocity variance due to phase noise is:
The noise approaches zero when αi approaches zero, representing a perfectly vertical borehole.
Fluctuations of the phase signal come from magnetometer noise, external magnetic field disturbances and fluctuations of the tool's rotational axis in relation to the borehole axis. System problems occur from disturbances and fluctuations of the tool's axis in relation to the borehole axis. The use of magnetometers to detect phase is problematic when the direction of the borehole approaches the direction of the earth's magnetic field vector.
Since the phase is calculated as:
the sensitivity of Φm to a By disturbance is:
which assumes its lowest value of 1/Bx when By=0. At this point, the value of Bx is sin(αm), where αm is the angle between the borehole and the earth's magnetic field vector. A symmetrical relationship exists for Bx noise, but a reasonable estimate can be based on just one magnetic field component since the influence of one component peaks when the influence of the other is the lowest. The phase noise caused by the magnetic signal noise can be expressed as:
According to Eq. (22), the phase noise increases as αm goes to 0, representing drilling along the earth's magnetic field vector. Combining Eq. (19) and Eq. (22) a formula linking magnetic field noise with velocity is derived:
The noise of the magnetic induction signal has three uncorrelated components: (1) magnetometer noise, which is a function of the device used to measure the magnetic field; (2) fluctuations of the tool's axis in relation to the earth's magnetic field; and (3) influence of the antenna-magnet. The noise of the magnetoresistive sensor, in this case a Honeywell HMC1002, for a bandwidth of 0.01-20 Hz, is under 6 μGauss rms with a variation of 36*1012 Gauss2.
The tool's axis is constrained by the borehole and, assuming a 30 ft distance between stabilizers and maximum 2 inch slack between the borehole wall and the stabilizer, as shown in
σB
where the variance of β is in radians2.
The magnetic field generated by the NMR magnet may produce additional noise if the position of the magnet changes in relation to the magnetometer owing to the deformation of the tool's structure or the magnetometer's mounting. Only components within the 20 Hz bandwidth are significant since higher frequencies will be filtered out.
When the tool is bent by an angle γ, the By component will change slightly.
A combined effect of all 3 magnetometer-related effects calculated according to (23) is shown in FIG. 21. The velocity uncertainty (1σ level) is below 0.015 m/s if the direction of the borehole is at least 1.5° apart from the direction of the earth's magnetic field vector. Otherwise, if the borehole direction is essentially parallel to the earth's field vector, the phase information has to be derived from the acceleration signals themselves.
Tables 4 and 5 summarize the uncertainty budget in accordance with a specific embodiment. It will be appreciated that the major contributor of random noise is the phase noise. The systematic error is dominated by the bandwidth limit. In accordance with the present invention, this error can be reduced in post processing by introducing phase correctors to reduce the group delay of the filters.
It will be readily apparent to those skilled in the art that various modifications may be made without departing from the spirit and scope of the invention. The scope of the invention shall not be limited to the embodiments described in the specification but shall be defined by the claims as appended.
The present application is a continuation of U.S. application Ser. No. 09/882,228, which was filed on Jun. 14, 2001 and issued as U.S. Pat. No. 6,518,756 on Feb. 11, 2003.
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Number | Date | Country | |
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Parent | 09882228 | Jun 2001 | US |
Child | 10713923 | US |