Boreholes are drilled into earth formations for various purposes such as hydrocarbon production, geothermal production, and carbon dioxide sequestration. In general, the boreholes are drilled by rotating a drill bit disposed at the distal end of a string of drill pipes referred to as a drill string. An assembly of the drill bit and other downhole tools at the end of the drill string may be referred to as a bottomhole assembly (BHA). Applying forces to the drill string to drill a borehole may result in vibratory behavior of the drill string and the BHA.
Different kinds of vibratory behavior exist in oil field drilling dynamics. These can be distinguished into axial, torsional, and lateral vibrations. Recently, high frequency torsional vibrations were observed in field tests with accelerations up to 100 g, which are potentially able to damage downhole tools. These vibrations can also be differentiated from stick slip by mode shapes, which are localized to the BHA. Hence, it would be well received in the drilling and geophysical exploration industries if a method could be developed to reduce high frequency vibrations of the drill string and BHA.
Disclosed is a method for reducing vibrations in a drill tubular coupled to a drill bit configured to drill a borehole in a formation. The method includes: constructing a mathematical model of a system having the drill tubular, the mathematical model comprising at least one of a mass distribution of the drill tubular, a stiffness of the drill tubular, and a damping of the drill tubular; calculating a plurality of modes using the mathematical model; and increasing an effective damping of the drill tubular for the plurality of modes by modifying at least one of the mass distribution of the drill tubular, the stiffness of the drill tubular, and the damping of the drill tubular using a predefined damping criterion; wherein the predefined damping criterion comprises a ratio, the ratio comprising a deflection at the drill bit of at least one of the plurality of modes and an eigenfrequency of the at least one of the plurality of modes, wherein the deflection at the drill bit is raised to a power other than one.
The following descriptions should not be considered limiting in any way. With reference to the accompanying drawings, like elements are numbered alike:
A detailed description of one or more embodiments of the disclosed apparatus and method presented herein by way of exemplification and not limitation with reference to the figures.
Disclosed is a method for reducing vibrations in a drill string induced by cutting forces from interaction of a drill bit with an earth formation being drilled. The method is explained using the example of self-excited vibrations due to a falling characteristic of the aggressiveness of the drill bit with respect to the angular velocity of the drill bit or drill string. Nevertheless, the method is also able to reduce vibrations in specific mode shapes, which are induced by any kind of cutting force at the drill bit (e.g., harmonic excitation forces and impacts). The method involves modifying vibratory mode shapes of the drill string, which includes a bottomhole assembly (BHA). The vibratory mode shapes may be modified by changing the distribution of mass, density of mass, structural or material stiffness, and/or damping characteristic of the drill string and/or BHA. While torsional vibrations and bit-rock interactions are discussed for teaching purposes, the method may be applied to other types of vibrations and any other source of self-excitation or excitation.
The BHA 10 in
Downhole electronics 11 may be configured to operate one or more tools in the plurality of downhole tools 9, process measurement data obtained downhole, and/or act as an interface with telemetry to communicate measurement data or commands between downhole components and a computer processing system 12 disposed at the surface of the earth 3. Non-limiting embodiments of the telemetry include pulsed-mud and wired drill pipe. System operation and data processing operations may be performed by the downhole electronics 11, the computer processing system 12, or a combination thereof. A processor such as in the computer processing system 12 may be used to implement the teachings disclosed herein.
The method disclosed herein calls for constructing a mathematical model of the drill tubular, the BHA portion of the drill tubular, and other components that may be coupled to the drill tubular. In one or more embodiments, the drill tubular is modeled as a finite-element network such as would be obtained using a computer-aided-design (CAD) software package. Non-limiting embodiments of the CAD software are Solid Works, ProEngineer, AutoCAD, and CATIA. The model may be a three-dimensional model, a two-dimensional model, or a one dimensional model (i.e., modeling just torsional vibration, just axial vibration, or just lateral vibration). The model includes a geometry of the drill tubular and material properties of the drill tubular such as density (e.g., to give weight distribution), stiffness (e.g., to determine flex), and/or damping characteristic. The stiffness data may include elasticity and/or Poison's Ratio. It can be appreciated that if a tool or component is configured to be a structural part of the drill tubular, then the tool or component will be modeled as part of the drill tubular. The model may also include geometry of the borehole so that external forces imposed on the drill tubular from contact with a borehole wall can be determined. The geometry may be determined from a drilling plan or from a borehole caliper tool, which may be one of the downhole tools 9.
Once a mathematical model of the drill tubular and BHA is constructed, the method calls for calculating motion of the drill tubular and BHA using an equation of motion. The equation of motion of the drill tubular and BHA may be written as:
M{umlaut over (x)}+C{circumflex over (x)}+Kx=f
where M is the mass matrix representing the mass of the drill tubular and the BHA, K is the stiffness matrix representing the stiffness of the drill tubular and the BHA, C is the damping matrix representing the damping response of the drill tubular and the BHA or other drill tubular components, x is the vector of physical amplitudes of motion of the drill tubular and BHA, and f is the vector of external excitation forces applied to the drill tubular and the BHA. The single dot represents the first derivative with respect to time and the double dots represent the second derivative with respect to time. This equation of motion of the drill tubular and BHA may be written in the modal domain as:
I{umlaut over (q)}+D{dot over (q)}+Λq=Φ
T
f,
applying the transformation x=Φq where Φ is the mass normalized modal matrix such that ΦTMΦ=I (T represents transpose of matrix) and q is the vector of modal amplitudes. I, D and A are the modal mass matrix or unity matrix, the modal damping matrix, and the spectral matrix containing eigenvalues of the system, respectively. ΦTf can be denoted as the modal excitation vector, which relates the vector of external excitation forces applied to the drill string and the BHA in the modal domain. The equation of motion in the modal domain may be diagonalized and described as:
diag({umlaut over (q)}i+2Diω0,i2qi)=ΦTf.
Herein, Di and ω0,i are the modal damping factor and the angular eigenfrequency of the i-th mode, respectively.
The physical interpretation of the modal domain is that it represents the frequencies (i.e., eigenfrequencies) and corresponding mode shapes (i.e., eigenmodes) relating to the free vibration of the drill tubular. At the eigenfrequencies, the drill tubular is more susceptible to excitation forces that cause the vibrations. Forces imposed on the drill bit by interactions of the drill tubular with formation rock such as by the cutting action of the drill bit may be referred to as self-excitation.
Assuming only one mode contributes to the vibrations (for simplicity of the mathematical derivation, but not limited to this assumption), the equation of motion written as:
{umlaut over (q)}
i+2Diω0,i{dot over (q)}i+ω0,i2qi=φiTf.
Assuming the last degree of freedom is the torsional degree of freedom of the drill bit, the physical excitation force vector may be written as:
f=[f
1
f
2
. . . f
bit]T.
Note that forces and torques are not distinguished in this context. If excitation forces and/or torques exist only at the drill bit, that is f1=f2= . . . =fn-1=0 and fn=force and/or torque at the drill bit, then the modal force of the i-th mode shape may be written as:
φiTf=[φ1,iφ2,i . . . φbit,i][0 0 . . . fbit]T=φbit,ifbit.
This leads to the equation of motion for modal amplitude qi of one mode shape φbit,i being written as:
{umlaut over (q)}
i+2Diφ0,i{dot over (q)}i+ω0,i2qi=φbit,ifbit
where the product φbit,ifbit is the modal force.
The physical degrees of freedom of the drill string-BHA structure can be described as:
x=Φq=[φ
1φ2 . . . φm][q1q2 . . . qm]T.
It is assumed that the cutting forces and modal amplitudes of one mode shape are not influenced by other mode shapes, which applies for a fully linearized model in general. This is true if the self-excitation tends to localize in one mode, which has been proven by observations from field tests.
The physical forces at the drill bit may be described by a falling or declining characteristic of the aggressiveness (related to amount of rock removed) with which the drill bit drills into formation rock with each revolution. (One interpretation of aggressiveness (μ) is μ=c*TOB/WOB where c is a constant, TOB is torque-on-bit and WOB is weight-on-bit. A falling or declining characteristic of μ generally results in a falling characteristic of fbit, if the WOB does not change significantly. This latter dependency is covered by the following equation.) The force acting on the drill bit may be described as:
where
is the slope of the falling friction force with regard to a constant rotational speed (rpm) or angular velocity
The parts of this equation of motion, which are proportional to the velocity, can be combined to an effective damping factor. The criterion for positive or effective damping is:
This relation can also be used to define a limit for the slope of the falling aggressiveness characteristic or friction forces of the drill bit with respect to angular velocity by being rewritten as:
This relation may be further rewritten for the modal damping Di needed to avoid self-excitation for mode i as:
Interpreting the results of these equations, the system (i.e., drill string and BHA) is more prone to self-excitation if the modal damping factor Di is lower, if the slope of the velocity dependent cutting forces
is higher, if the angular eigenfrequency ω0,i is lower, and if the mode shape has a higher value φbit,i at the drill bit. Since the latter contributes quadratically, it has a very high impact on the stability (or system vibrations) of the system.
Recapitulating, self-excitation of a specific mode shape φi with a specific angular eigenfrequency ω0,i and modal damping factor Di caused by velocity dependent
cutting forces (see
can be interpreted to provide the following criteria to avoid or limit vibrations resulting from self-excitation.
Increase the modal damping Di of the observed mode to avoid self-excitation of the mode shape. Modal damping may also be increased by increasing the deflection of the mode shape in areas with high material damping (e.g., if rubber is deformed) or where friction contacts, such as at high amplitudes, dissipate energy.
Reduce the slope
of the falling friction characteristic. The slope is dependent on the formation, drilling fluid or mud, and drill bit properties.
Increase the angular eigenfrequency ω0,i of the mode to reduce the risk of self-excitation as defined above. This is dependent on the mass and stiffness distribution along the BHA (e.g., reducing masses and increasing stiffness).
Due to the quadratic contribution, the drill bit deflection described by the mode shape factor φbit,i2 has the highest influence on the described condition. Changing mass and stiffness distribution can reduce this deflection. This may compete with the goal to increase the eigenfrequency.
Mathematically, the above criteria can be described by maximizing the distance of the effective damping to the regime of self-excitation for all significant mode shapes as follows:
Herein, F is a function of the manipulating stiffness ΔK (i.e., change in stiffness due to manipulation), damping ΔC (i.e., change in damping due to manipulation), and mass ΔM (i.e., change in mass due to manipulation) matrices added to the system and also of the properties of the drill bit.
The constraint
for i=1 . . . n prohibits self-excitation if Di*≥0. Di* should be selected to be greater than zero to have a security or margin factor. Another constraint might be necessary to limit the additional mass Δmj≤Δ
The above optimization problem can be solved by intuitively changing mass and stiffness distribution along the drill tubular or with an optimization algorithm such as Nelder-Mead is a non-limiting embodiment.
in order to obtain one or more critical mode shapes. The critical mode shapes provide maximum margin to avoid self-excitation leading to damaging vibrations of the drill tubular.
The above disclosed techniques provide several advantages. One advantage is that the techniques provide for increasing the reliability of downhole tools or components by reducing vibration levels to which the tools and components may be subjected. The techniques are also economical compared to the alternative of trial and error during field operations. It can be appreciated that, when the BHA includes one or more accelerometers, the measured accelerations can be compared to the predicted accelerations as a validation or quality check of the techniques.
In support of the teachings herein, various analysis components may be used, including a digital and/or an analog system. For example, the downhole electronics 11, the computer processing system 12, or the sensor system 9 may include digital and/or analog systems. The system may have components such as a processor, storage media, memory, input, output, communications link (wired, wireless, pulsed mud, optical or other), user interfaces, software programs, signal processors (digital or analog) and other such components (such as resistors, capacitors, inductors and others) to provide for operation and analyses of the apparatus and methods disclosed herein in any of several manners well-appreciated in the art. It is considered that these teachings may be, but need not be, implemented in conjunction with a set of computer executable instructions stored on a non-transitory computer readable medium, including memory (ROMs, RAMs), optical (CD-ROMs), or magnetic (disks, hard drives), or any other type that when executed causes a computer to implement the method of the present invention. These instructions may provide for equipment operation, control, data collection and analysis and other functions deemed relevant by a system designer, owner, user or other such personnel, in addition to the functions described in this disclosure.
Elements of the embodiments have been introduced with either the articles “a” or “an.” The articles are intended to mean that there are one or more of the elements. The terms “including” and “having” are intended to be inclusive such that there may be additional elements other than the elements listed. The conjunction “or” when used with a list of at least two terms is intended to mean any term or combination of terms. The term “coupled” relates to a first component being coupled to a second component either directly or indirectly via an intermediary component.
While one or more embodiments have been shown and described, modifications and substitutions may be made thereto without departing from the spirit and scope of the invention. Accordingly, it is to be understood that the present invention has been described by way of illustrations and not limitation.
It will be recognized that the various components or technologies may provide certain necessary or beneficial functionality or features. Accordingly, these functions and features as may be needed in support of the appended claims and variations thereof, are recognized as being inherently included as a part of the teachings herein and a part of the invention disclosed.
While the invention has been described with reference to exemplary embodiments, it will be understood that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications will be appreciated to adapt a particular instrument, situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.
The present application is a continuation of U.S. patent application Ser. No. 14/070,130 filed Nov. 1, 2013, of which is hereby incorporated in its entirety herein.
Number | Date | Country | |
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Parent | 14070130 | Nov 2013 | US |
Child | 15970585 | US |