91871081 Buckling o Pandeo en Las Tuberias
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Transcript of 91871081 Buckling o Pandeo en Las Tuberias
BUCKLING O PANDEO
El buckling o pandeo es un fenómeno de inestabilidad elástica que puede darse en elementos comprimidos y que se manifiesta por la aparición de desplazamientos importantes transversales a la dirección principal de compresión, como se muestra en la siguiente gráfica.
Deberá tenerse este factor muy en cuenta en el momento del diseño de la sarta de perforación o de producción ya que normalmente tales diseños se realizan al llamado factor de diseño límite. El pandeo producido en las tuberías flexibles que están sometidas a una carga crítica. Para esto debe considerarse el factor de seguridad entre la carga real y la carga crítica resultante de la presión del terreno, presión de agua subterránea y la suma de estas presiones.Durante la colocación del tubo es recomendable provocar una deformación u ovalamiento vertical del 2%-3% sirviéndose de la compactación de los laterales. De esta manera se pre-esfuerza el tubo, mejorando su resistencia al abollamiento.
Para el cálculo de la tensión crítica de pandeo se utiliza la fórmula de Timoshenko:
Pc = 3*E*I (1-v2) r3
Siendo:
Pc: Presión crítica de pandeoE: Módulo de elasticidad del PVCI: Momento de Inercia de la pared del cañor: Radio interno del cañov: Relación de Poisson
PVC = 0.38 ACERO = 0.27 – 0.30 ACERO INOXIDABLE = 0.31
En los casos en que las tuberías estén totalmente llenas de líquido a presión, se puede producir abolladura o pandeo por el efecto de vacíos creados en los caños. Es por esto que deben aplicarse métodos para la remoción de estos vacíos en los puntos correspondientes (válvulas automáticas, etc.).
Elementos que fallaron por Pandeo.
Ejemplo de una sarta de perforación en el campo petrocedeño, que extrae crudos extra pesados, en una zona formada por granos gruesos con alta permeabilidad, teniendo espesores de arena promedio de 40 pies. y poca compactación de los granos de las arenas petrolíferas.
Modificando la sarta para hacerla más equilibradaTradicionalmente se había venido usando en Petrocedeño una sarta direccional organizada de la siguiente forma:•Mecha•Equipo direccional•Tubería de perforación (DP)•Tubería pesada de perforación (HWDP)•Porta mechas (Drillcollars)
Un largo tramo de tubería de perforación (DP) proporcionaba buen peso al principio de la perforación y bajo roce cuando la tubería estaba horizontal. Sin embargo ocurría un efecto negativo debido a la flexibilidad: el pandeo o buckling, que hacía que la tubería se pegara a los lados del pozo aumentando el roce. Esto no ocurría con la tubería pesada de perforación (HWDP) porque era menos flexible.Fue así que el equipo de Perforación Direccional y el equipo deIngeniería de perforación probaron una sección de tubería híbrida.Constaba de ciclos de 5 tubos de DP y un solo tubo de HWDP. Esta configuración continuaba siendo liviana (y de bajo roce), pero el tubo de HWDP intercalado minimizaba el pandeo.
La sarta de perforación que actualmente utiliza Petrocedeño se compone así:• Mecha• Equipo direccional• Tubería de perforación (DP)• Tubería Híbrida (5 DP + 1 HWDP)
• Tubería pesada de perforación (HWDP)• Porta mechas (Drill collars)
TORQUE Y DRAG
TORQUE
Definiendo el torque t de una fuerza f que actúa sobre algún punto de un cuerpo rígido, para facilitar el análisis, en una posición r, respecto de cualquier origen o, por el que puede pasar un eje perpendicular, sobre el cual se produce la rotación del cuerpo, al producto vectorial entre la posición r y la fuerza aplicada f:
T = r ∗ F
T= Torque
R= Radio de acción
F= Fuerza aplicad
El torque que se presenta en la perforación, es la fuerza mecánica generada por el Top Drive/Mesa Rotatoria, necesaria o aplicada para hacer rotar la sarta de perforación para vencer las fuerzas presentes a lo largo de la trayectoria del pozo.
ARRASTRE O DRAG
El arrastre es una fuerza mecánica, generada por la interacción entre un cuerpo rígido y un fluido. Para que exista arrastre el cuerpo debe estar en contacto con el fluido. Debe haber un movimiento relativo entre el fluido y el sólido. Esta resistencia que impide la aceleración del cuerpo se llama fuerza de arrastre.
El arrastre presente en la perforación es la fuerza que se produce entre las superficies de contacto de las conexiones de tubería y las paredes del pozo que se esta perforando causado por el deslizamiento y la rotación de la sarta de perforación. El arrastre es una de las cusas por las cuales se produce el efecto de pandeo en las tuberías.
En la siguiente figura se muestran los esfuerzos a los que esta sometida la sarta de perforación.
Para fines de diseño, el calculo de torque y arrastre debe incluirse con factores de fricción críticos, en todos los casos de cargo, asi se asegura la respuesta en resistencia a la torsión y a la carga axial de los tubulares. De esta manera se garantiza que la tubería sea introducida, rotada, deslizada y jalada.
La evaluación o modelación del torque y arrastre en las tuberías, se realiza con varios propósitos:
Para seleccionar la tubería con suficiente resistencia al torque y a la carga axial Determinar los requerimientos del equipo Optimizar la trayectoria en pozos desviados Analizar el efecto de desgaste en tuberías
También se han desarrollado algunas herramientas que reducen el torque y el arrastre como lo son :
LoTAD™ (sustituto). LoTORQ™ (centralizador de rodillos). LoDRAG™ (centralizador de rodillo). Herramienta CRS (Completions Running String), con énfasis en problemas
frecuentes en pozos de alcance extendido y profundos (pega diferencial, pandeo y vibración, desgaste de TJ y revestidor, torque y arrastre elevados y limpieza del hoyo).
Coiled tubing fatigueCoiled tubing (CT) well intervention and drilling operations require that the continuous-length tube be
subjected to repeated deployment and retrieval cycles during its working life. The tubing stored on a
service reel is deployed into the wellbore to the designated depth and then retrieved back onto
the service reel. The working life of the CT may be defined as the duration of service for the continuous-
tubing string when subjected to the following conditions:
Bend-cycle fatigue
Internal pressure loading
Applied axial loading
Corrosion
Mechanical damage
All of the aforementioned items act on the tube body to some degree during any CT service and
contribute to the eventual mechanical failure of the tubing. To ensure safe and reliable well intervention
and drilling operations, the user must understand the unique behavior of CT to minimize the possibility of
tubing failure. Numerous decisions must be made throughout the working life of a CT string to maximize
the remaining life. From this approach, the decision to retire the tubing must be made on the basis of
current tube conditions, service history, and the anticipated service loading.
Bend-cycle fatigueFatigue is generally considered to be the single major factor in determining the working life of CT. The
deployment and retrieval of the continuous-length tubing string require that the tube be subjected to
repeated bending and straightening events, commonly referred to as “bend-cycling.”
The amount of strain imposed upon the tube body during the bend-cycling process is considered to be
enormous, in many cases on the order of 2 to 3%. When subjecting the CT to this type of fatigue cycling,
the stress and/or strain fluctuations to failure may be estimated using conventional axial fatigue life
prediction approaches.[1]
However, when the bend-cycling process is coupled with internal tube pressure loading, conventional
multiaxial life prediction approaches cannot accurately predict CT behavior. Numerous tests performed
have confirmed the fact that bend-cycling CT with internal pressure loading dramatically reduces the
fatigue life of the tube when compared to the cycle life of unpressurized tubing. This happens despite the
fact that the tangential (hoop) stresses imposed by typical “high” pressures in CT service are on the
order of only 50 to 60% of nominal yield strength . However, when combined with fluctuating axial strain
ranges on the order of 2 to 3%, significant cyclic ratcheting (ballooning) occurs, and fatigue damage
development is accelerated. Outside of the CT industry, there are essentially no other applications
involving steel alloys in which cyclic loading of this magnitude is intentionally imposed and expected to
survive the prescribed service.[2]
Stress and strain in HSLA steel
To better understand the abuse imposed upon CT during normal service operations, a brief review of the
relationship between stress and strain in high-strength low-alloy (HSLA) steel is given next. Fig. 1 is a
typical stress-strain curve for HSLA steels. The axial stress, α, is plotted along the Y-axis, and the
corresponding axial strain, ε, is plotted along the X-axis. As stress is applied to the steel material, a
corresponding strain develops as defined by Hooke’s law that states that the amount of stress is equal to
the amount of strain, multiplied by the modulus of elasticity of the material. This relationship is graphically
represented as the line segment O-A in Fig. 1, where the modulus of elasticity defines the slope. The
stress at Point A is referred to as the “proportionality limit,” also referred to as the “elastic limit.” As long
as the stress levels within the steel are held below the elastic limit, the strains are also considered to be
elastic, and no permanent deformation will occur.
Fig. 1—Stress/strain relationship representing behavior of HSLA material (courtesy of Dr. Steve
Tipton,U. Tulsa).
However, as increased stress is applied to the steel, the elastic limit is exceeded and will reach Point B,
which is termed the "yield point". The yield point defines the yield strength , Sy, or the stress that causes
the initiation of plastic strain in the material. Once the yield point is reached, permanent deformation
occurs, and plastic strain is developed as the material begins to elongate permanently.
To determine the yield strength of alloy steel materials in a consistent manner, a standard 0.2% offset
plastic strain value was adopted to locate the yield point on the stress-strain curve. This is shown as the
dotted line "AB-X.2%." Loading into the plastic region to Point P, followed by unloading to Point O, Line P-
O is usually believed to also define the slope of the modulus of elasticity and intersect the X-axis to
represent the amount of plastic strain resulting from the deformation. However, it has been shown that
plastic deformation tends to reduce the modulus of the elastic unloading curves by as much as 15 to
20% for loading typically seen in CT well intervention and drilling services.
By applying additional stress, we will reach Point D, which is referred to as the ultimate tensile strength of
the material. Once Point D is reached, the material will suffer a separation failure.
The amount of stress experienced by the HSLA material can be fully appreciated when considering the
degree of bending the tube must undergo during conventional service activities. The radii of typical CT
service reels and tubing guide arches are significantly less than the yield radius of curvature (RY) for any
given size of CT listed. When the tubing is bent and wound onto the service reel or storage spool, the
HSLA steel is yielded and becomes plastically deformed. This plastic deformation event is similar to the
graphical illustration seen in Fig. 1 as Curve O-P. When the amount of stress applied to the tubing is
relaxed, the strain remaining is permanent and has a value represented by the extension of Line P-O'.
The bend event sequenceThe fatigue imparted to the CT material during normal service operations is the result of bending the
continuous-length tubing beyond its elastic limit and forcing the material into plastic deformation. Fig.
2 illustrates the typical operating sequence whereby bend cycles are imposed on the CT during
deployment and retrieval. For this illustration, the initial state of the tubing will be in the "as wrapped"
condition on the service reel. The bend event sequence is described next.
Fig. 2—Bending events occurring during CT operations (courtesy of Dr. Steve Tipton, U. Tulsa).
The tubing is pulled off the service reel by the injector. The hydraulic motor on the reel provides
resistance to the pull of the injector, placing the tubing in tension. The tension applied is typically
limited to the amount needed to bend the tubing over the tubing guide arch and maintain control of
the tube during deployment. Therefore, the tubing is straightened out somewhat, constituting the first
bend event.
Once the CT reaches the tubing guide arch, the tubing is bent over the prescribed radius. This event
constitutes the second bend event experienced during deployment.
As the tubing travels over the tubing guide arch, the tubing is returned to the straightened orientation
before entering the gripper blocks in the injector (third bending event).
These three bending and straightening events are repeated in reverse as the tubing is extracted from the
well, resulting in a total of six bending events commonly described as a “trip.”
In relative terms, the smaller the bending radius, the larger the value of bending strain induced into the
tube segment. This is seen as the more severe bending strains imposed when the CT is cycled over the
service reel, as compared to the less severe bending strains imposed when bending occurs over the
tubing guide arch. Therefore, during a complete service trip, the tubing will experience two bending
events inducing relatively higher bending strain and four bending events inducing relatively lower
bending strain. Note that the pairing of two bending events with equivalent strain magnitudes is defined
as a “bend cycle.” Therefore, within each CT service trip, there are two relatively low-strain bend cycles
and one relatively high-strain bend cycle.
In general, for CT well-intervention and drilling operations, the number of trips assigned to the tubing is
not the same over the entire length of the tubing string. For example, during routine service work, it is
common to periodically stop deployment and reverse the motion of the CT string, retrieving a prescribed
length of tubing back out of the wellbore to check weight and drag of the tubing. The intermediate
segments of the tubing string, which were subjected to these “drag checks,” will have a greater number
of trips allocated than that which is allocated to the remainder of the tubing string. In addition, where a
prescribed service program requires repeated bend cycling over a specified segment of the tubing string,
this segment will have an accumulation of fatigue damage that is significantly greater than the fatigue
damage subjected to the remainder of the tubing-string length.
The discussion on CT bend cycling makes apparent that most of the material fatigue occurs at the reel
and tubing guide arch, with very little, if any, within the wellbore. In CT services, the plastic deformation
of the tube material that results in the cumulative damage is defined as “ultralow cycle fatigue.” The
loading in ultralow cycle fatigue is plastic, and failure of the material generally occurs within 2,000 bend
cycles.
The occurrence of microcracks in CT operations
A consequence of ultralow cycle fatigue in CT operations is the eventual formation of microcracks in the
tube body. With continued bend cycling, the cracks propagate through the tubing wall until the crack
establishes full penetration from one side of the wall to the other. Once the crack has fully translated
through the tube body wall, pressure integrity is lost. Typically, the initial size of the crack is very small,
making detection of this type of body damage very difficult. Furthermore, cracks tend to initiate on the
inner wall of the tubing, despite the fact that the bending strain is greater on the outer surface. In
conditions in which high internal pressure is present, the hoop stress may cause the crack to
instantaneously propagate along the circumference of the tube. In this condition, a major transverse
crack will occur and may result in the mechanical separation of the tubing. For this reason, crack
initiation is typically the criterion used to define “failure” within a CT section.
Bend cycle test and data
Loss of pressure integrity in any condition makes the CT string unfit for service. At present, the fatigue
condition of a segment of tubing with an unknown bending history cannot be accurately measured
nondestructively. Because fatigue appears to be a statistical phenomenon, variations can be expected in
observed fatigue life for any sample, regardless of comparable bending history records.
Various types of bend-cycle fatigue test machines (Fig. 3) have been developed in an attempt to
simulate the wellsite bendcycling of CT over a constant radius with internal pressure loading. These
bend-cycle fatigue fixtures generate a statistically significant quantity of fatigue data and provide a
means to estimate bend-cycle fatigue over a wide range of test conditions.
Fig. 3—Illustration of CT fatigue testing machine (courtesy of Dr. Steve Tipton, U. Tulsa).
Numerous analyses of the trends recorded from the ever-increasing volumes of CT fatigue tests suggest
that bend-cycle events imposed onto a given tubing specimen with high internal pressure (causing hoop
stresses on the order of 30 to 60% of the yield strength ) accumulate fatigue damage at a much greater
rate than bendcycles imposed with low internal pressure loading.
In addition, the magnitude of fatigue damage realized from a given bend-cycle event cannot be applied to
working-life predictions in a linear fashion. Evidence from the volume of testing suggests that a given
bend-cycle load applied later in the tube working life may cause greater fatigue damage than the
equivalent bend-cycle load applied earlier in the tube working life. The bend-cycle fatigue data obtained
from the test fixtures has also provided insights into several other areas of CT service behavior. These
items are discussed next.
“Cyclic softening” of CT materialOne significant consequence of repeated bend cycling of CT material is a phenomenon referred to as
“cyclic softening,” which results in a reduction in material yield strength as the CT performs its prescribed
service.[3] The magnitude of the cyclic softening realized in CT materials can be directly related to the
amount of material strain imposed during service.
Standard strain-controlled, low-cycle fatigue testing is commonly performed on axial-test coupons of a
specified material to evaluate its behavior when subjected to fluctuating strain conditions. These tests
attempt to simulate the magnitude and intensity of the strain fluctuations anticipated during the
prescribed service and are used to help predict the fatigue strength of the material at the test conditions.
For steel CT products, similar types of stress-cycle tests have been performed to provide insight into
fatigue life and performance when subjected to multiaxial plastic deformation events.
The strain-controlled fatigue-testing process is illustrated in Fig. 4, in which the CT material is cut into the
designated test coupon geometry and installed into a fatigue test machine that subjects the material
specimen to strain-controlled, axial load cycles between a maximum and minimum strain, γmax and γmin . In
these tests, cyclic softening was observed because the peak stresses 3, 5, and 7 continually diminish
from the initial peak at Point 1.
Fig. 4—Cyclic softening of coupon during strain-controlled fatigue test (courtesy of Dr. Steve Tipton,
U. Tulsa).
The stress/strain diagram shown in Fig. 4 illustrates the hysteresis effect observed during the strain-
controlled axial-stress load-cycle tests. If plotted in terms of stress vs. time as shown schematically
in Fig. 5, the coupons exhibit a transient stress response, in which the recorded peak stress values
diminish incrementally relative to the previous value. This cyclic softening corresponds to a reduction in
the material yield strength . Eventually, stable hysteresis loops form, reaching a condition described as
"cyclic stabilization" of the material. In the conventional low-cycle fatigue tests conducted on the material
coupons, cyclic stabilization appears to occur when the accumulated fatigue damage is within the range
of 20 to 40% of expended cycle life.
Fig. 5—Stress history of coupon during strain-controlled fatigue test (courtesy of Dr. Steve Tipton, U.
Tulsa).
The material strain imposed during bend cycling of full-body CT specimens is considered to be at the
upper limit of the low-cycle fatigue regime, especially because this bending can combine with pressure to
cause lives on the order of fewer than 20 cycles. As previously discussed, the category that best
describes the behavior of CT bend-cycling is that of “ultralow cycle fatigue.” At the strain levels realized
during full-body CT bendcycling over typical bend radii, the bulk of the material softening can be seen
within the first few load cycles, with continued material softening occurring over the remainder of the tube
cycle life. For full-body CT bendcycling, truly stable stress responses may not be achieved, and cyclic
stabilization may never be truly realized.
The importance of this discussion becomes apparent when considering that the strain range experienced
in CT services varies significantly from point to point around the circumference of the tube body. At
positions between the points of maximum stress (i.e., the top and bottom of the tube body) and the
neutral axis, the intermediate strain ranges and transient material softening will most likely occur
throughout the entire working life of the tube. As a result, material strength and performance properties
can be expected to vary relative to the position around the circumference of the tube body. In some CT
material samples tested, the reduction in yield strength was found to be as much as 10 to 20% of the
parent material yield strength .
In actual service, the neutral bending axis on the CT when deployed into the wellbore will most likely be
in a different orientation on the tube circumference from when it is retrieved from the wellbore. This
change in neutral bending axis may be the result of relaxation of residual stresses in the tube when axial
tensile forces are applied during deployment into the well or because of some other phenomena.
During the extraction process, the tubing is retrieved into the injector gripper blocks with the previous
neutral axis rotated slightly off alignment. Once the tube is secured into its “new” orientation relative to
the gripper blocks, a new neutral axis will be defined as the tubing is bent over the tubing guide arch.
This repositioning of the neutral axis during well intervention and drilling operations is believed to
distribute the high-strain bend cycles around the circumference, creating a more uniform accumulation of
fatigue damage within the tube.
Diametral growthWhen subjected to plastic deformation because of bendcycling with internal-pressure loading, the
diameter of the CT tends to grow or “balloon.” Even when the internal pressure loading is well below the
yielding stress of the material, the tube body is subjected to hoop and radial stresses that cause the
material to grow macroscopically in diameter and to decrease in wall thickness (Fig. 6). In uncontrolled
fatigue tests, diametral growth exceeding 30% has been observed. The primary factors influencing
diametral growth are material properties, bend radius, internal-pressure loading, tube outside diameter
(OD), and tube wall thickness.
Fig. 6—Illustration of typical diametral growth for CT (courtesy of Dr. Steve Tipton, U. Tulsa).
Interaction with surface handling and pressure-control equipment
One major concern for diametral growth is the interaction with surface handling and pressure-control
equipment. The injector gripper block loading on CT usually has an impact on the tube geometry, and the
effect tends to vary according to variables such as:
The magnitude of gripper block normal force
Block geometry and wear
CT geometry, internal pressure, and material type
Most conventional counter-rotating chain injectors have gripper blocks that are machined to fit the OD of
the specified size of tubing. When CT experiences diametral growth, the increase in tube size creates a
nonsymmetrical loading condition, concentrating the normal force load at contact points on the edges of
the gripper block. These focused stress concentrations induce additional damage into the tube body and
result in added tube deformation.
Some injector manufacturers have made adjustments to the design of the gripper blocks in an attempt to
minimize this additional damage to the tube. The segmented-type and “variable”-type gripper-block
designs appear to better accommodate increases in tube body growth. However, as the diametral growth
of the tube increases, the two-point contact loading of the gripper blocks will induce lines of concentrated
stress on the tube body. With this focused stress concentration, the gripper blocks will impart greater
damage onto the tube at the normal force loads typical for properly fitted gripper blocks.
Another concern for diametral growth relates to the interaction with the pressure-control equipment. The
stripper assembly contains brass bushings that are used to prevent extrusion of the elastomeric
elements. These bushings have an internal diameter that is slightly larger than the specified OD of the
tubing. If the actual CT diameter on any axis reaches or exceeds the internal diameter of the brass
bushings, the CT will bind up within the bushings, resulting in surface damage to the tubing. Once this
condition is reached, the CT may no longer pass through the stripper. To prevent this situation,
limitations should be placed on the maximum allowable CT diameter.
Absolute diameter
The recommended method of defining maximum allowable growth of CT is “absolute diameter,” at which
the CT is retired from service when the diameter reaches a given value greater than its specified
dimension. The limit typically used is 0.050 in. and can be considered valid for all CT sizes when the
aforementioned type of stripper apparatus is used.
Observations of bend-cycle fatigue testing directly relating to diametral growth in CT are listed next.
The growth rate of the OD increases with increasing internal-pressure loading.
The diametral growth of larger-diameter CT as a percentage of specified diameter is greater than
that of smaller-diameter CT.
CT specimens with higher material-yield-strength demonstrate less diametral growth than lower
material-yield-strength specimens.
Mechanical limitations of surface handling and pressure-control equipment tolerances for allowable
diametral growth restrict the effective working life of CT in high-pressure service to only a fraction of
the projected fatigue life.
Differential wall thinningAs a consequence of diametral growth, CT experiences differential wall thinning. If we assume that the
cross-sectional area of the tube body is constant, then as the diameter grows, the redistribution of
material causes the wall of the tube to get thinner. The concept of differential thinning is also illustrated
in Fig. 6.
As the tube is bend cycled about the neutral axis, the top and bottom of the tube are subjected to the
highest stress concentrations and subsequently experience the greatest amount of thinning. Note that
the wall thickness at the neutral axis (where no bending stress occurs) remains at the initial wall
thickness. Therefore, the wall-thinning process is not uniform. Although the severe ballooning and
localized wall-thickness reduction are typically observed on samples tested in the laboratory, such gross
geometric changes are rarely seen in the field. This is because of factors such as tubing rotation (which
causes the wall thinning to occur more uniformly) and the ID of the stripper brass bushings (which limit
the use of tubing having excessive diametral growth).
Although extensive diametral growth and wall thinning are observed in the lab, empirical data obtained
from extensive full-scale field cycle testing conducted by Walker et al.[4] has shown that for a 3% increase
in tube body diameter, the wall thickness tends to decrease approximately 7.5%, resulting in a loss of
burst and collapse pressure rating of as much as 10%.
The mechanics behind the phenomena of diametral growth and wall thinning is referred to as transverse
cyclic ratcheting, whereby material deforms permanently with each cycle of loading in directions
transverse to the major fluctuating load directions. Conventional incremental plasticity theory has been
shown to overpredict cyclic ratcheting in the typical CT loading regime. Therefore, refined plasticity
models have been developed and used successfully to predict the behavior of CT samples in the lab and
the field.
Tubing length extensionAs a result of the stress/strain response exhibited by CT material (as seen in Figs. 1 and 4), the tubing
enters the well with a significant distribution of residual stress. The residual stresses vary from tension on
one side to compression on the other, at magnitudes equal to the material’s cyclic yield strength. This
residual stress profile has a first-order influence on the load-deflection behavior of the tubing and tends
to induce secondary deformation mechanisms which contribute to permanent increases in tube length.
This condition is commonly described as “elongation,” but should not be confused with the API definition
of elongation, which represents the change in specimen gauge length once ultimate tensile strength is
exceeded during a destructive tensile test. To avoid confusion, the term “extension” is used in this text to
refer to the observed permanent increase in CT length resulting from realignment of residual stresses
where axial force loading is applied.
As with diametral growth, extension occurs despite the fact that the applied axial stress (in terms of load
over cross-sectional area) is maintained to a value substantially below the material yield stress. The
investigation of extension was prompted by observations in coil-tubing drilling (CTD) operations where
the bottomhole assembly (BHA) could not return to maximum deployed depth after the string was
retrieved to surface and then redeployed to depth (referenced by painted points on the reel). The
reported “stack-out” depth was several feet higher than the previously reached depth, in excess of
calculated corrections for tube helix reorientation within the well. Extraction and subsequent
redeployment of this CT string found the stack-out depth several feet higher than the previous “stack-out”
depth, prompting concern for accurate depth control. Other onsite observations found that the amount of
permanent tube length increase was greater for new tubing strings as compared to “seasoned” tubing
strings.
Detailed studies have documented that extension occurs during high-pressure/constant-pressure bend
cycling because of the constant axial stress caused by pressure loading on the end caps. When higher
tensile loads are applied to the tube immediately after bend cycling has occurred, the section of the tube
wall with residual tensile stresses equal to the yield strength cannot sustain any more axial stress.
Therefore, the residual stresses within the tube body are redistributed to reach equilibrium, resulting in a
permanent extension of tube length.
The intensity of the residual stress distribution in the tube body is directly related to the imposed strain,
which suggests that the amount of extension for a given axial load increases as the bend radius is
reduced. Therefore, the location of maximum tube-length extension within the string will typically be in
the region where the smallest bend radii and highest axial tensile loads are imposed. This region of the
tubing string is typically located near the core diameter of the service reel (reference end), with high axial
loading resulting from the weight of the tubing suspended within the wellbore.
Multiaxial plasticity models have been developed to compute stresses and strains induced by the surface
handling equipment (tubing guide arch and service reel), internal pressure loading, and axial loads
experienced by the tube. These complex and sophisticated algorithms handle highly nonproportional
loading and must accommodate changes within the tube cross section as well as axially along the entire
length of the string. Therefore, the accuracy of the plasticity model predictions depends upon the proper
mapping of imposed strains throughout the service life of the tubing string.
Mechanical damageThe bend-cycle fatigue life of a CT string is also sensitive to surface damage, such as:
Scars
Scratches
Gouges
Dents
These types of mechanical damage serve as localized stress-strain concentrations where repeated bend
cycling can cause cracks to develop in the tube body.
Testing was performed by Quality Tubing to quantify the reduction in bend-cycle fatigue life for 1.750-in.-
OD, 0.134-in.-wall-thickness tube samples, with and without surface damage present.[5] The 80-ksi-yield
tubing samples were subjected to bend-cycle testing over an equivalent 72-in. bend radius with a 3,000-
psig internal pressure. A baseline test was performed with an undamaged tube and survived
approximately 725 bend cycles before loss of internal pressure (failure). Two samples were prepared
with transverse notches cut to an approximate depth of 10% of wall thickness. One sample located the
notch across the longitudinal weld seam, with the other sample locating the notch 180° from the
longitudinal weld seam. Both of these samples survived approximately 120 bend cycles, yielding an 83%
reduction in fatigue cycle life relative to baseline.
Two additional samples were prepared with the 10% wall thickness notches located at the same
positions on each tube body, but these notches were ground out and polished smooth before being
subjected to bend cycling. By removing the transverse notches, the tube samples survived approximately
590 bend cycles, yielding a 19% reduction in fatigue-cycle life relative to baseline. With the removal of
the surface damage, the bend-cycle fatigue life increased from 120 to 590 cycles, a 390% improvement
in survival life.
A recent study has noted that not only is the geometry of the defect important (length, width, depth and
shape of the defect), but also the mechanism by which the defect was imposed into the tubing. [6] For
instance, ball-nosed end mills were used to cut hemispherical defects into a set of CT samples. In
another set of tubes, defects with identical geometries were imposed by pressing hard balls into the
surface, rather than removing material by machining. When tested under identical constant amplitude
bend cycling, the samples with the milled defects reduced the life of the samples by as much as 60%
(relative to defect-free baseline samples), while the impressed defects caused virtually no life reduction.
Significant research is currently under way to quantify the influence of defects on CT life, as well as the
effectiveness of repair strategies, such as simple removal by surface grinding. The research currently
under way is addressing the influence of material grade and loading parameters such as:
Bending radii
Pressure
Tube geometry
An important component of the research is the incorporation of CT inspection technology. The most
prevalent CT inspection technique is magnetic flux leakage. Although this technique has proven effective
in detecting the presence of a flaw, existing technology provides no information about the severity of the
flaw.
The research currently under way has made important steps[7] toward extracting quantitative information
about the geometry of the defect, as well as its influence on fatigue. Over time, a continually growing
database will facilitate the development of refined signal-processing algorithms that provide important
feedback directly from magnetic flux leakage results.
Surface ripplingAn additional phenomenon that occurs as a result of CT bend-cycle fatigue is described as “surface
rippling.” It is common to find “ripples” developing on the top surface of the CT (relative to the neutral
axis) when subjected to bend cycling in combination with high internal-pressure loading. On many
samples examined, the period of the ripple formation has typically been observed to be approximately
twice the tube diameter.
This condition has been observed to occur both in field service operations and with tube specimens
tested in fatigue cycle fixtures. This consequence of bend cycling is attributed to the fact that CT does
not yield continuously along its length as it is deformed. What occurs is more of a buckling phenomenon,
where the outer fibers simply lengthen to a point where they buckle in compression when straightened
and never quite return to a perfectly straight condition upon rewrapping. Rippling typically occurs
relatively late in the fatigue life of the tubing. Therefore, if surface rippling is observed in the CT, it is
recommended that the tube be immediately withdrawn from service.
Effects of bend cycle fatigue on weldsWelds of several types are fundamental to the manufacture of steel CT. Welds are a common concern
because the bend-cycle fatigue life of certain welds can be significantly less than that of the parent tube
material. As a result, the performance of welds is of critical importance to the working condition of the
tubing string as a whole.
The longitudinal seam weld runs the entire length of the coiled tube and is created during the
manufacturing process as the base skelp is formed into tubing in the mill. Problems with the longitudinal
seam weld are usually detected at the mill during either the manufacturing process or the subsequent
hydrostatic pressure testing procedure. However, failures along the seam have occurred during field
services in high-pressure applications because of excessive triaxial stress loading.
During laboratory CT fatigue testing, it has become common practice to place the longitudinal weld seam
along the curved bending mandrel or on the compressive side of the tube wall. In general, cracking
occurs on the compressive side of the tubing at least as often as (if not more often than) it does on the
tensile side of the tubing. This observation holds even for testing when the weld seam is placed along the
neutral axis of the tubing.
In general, tests performed on the orientation of the longitudinal weld, with respect to the bending axis,
have found no correlation of cycle fatigue life reduction because of longitudinal seam-weld damage. In
the process of derating the CT because of bend cycling, the longitudinal weld is generally disregarded.
Skelp-end weld
The welding technique that joins base metal skelp is referred to as the skelp-end weld. The flat skelp is
cut and welded at an approximate 45° angle, causing the weld to form a helical wrap around the tube
girth when the strip is subsequently formed into a cylinder. The weld is typically made in ideal conditions
(with full control over the geometry and weld penetration), resulting in a weld of high and consistent
quality.
The skelp-end weld performs favorably in bend-cycle fatigue tests because of the:
Quality control
Treatment of the weld
Subsequent helical distribution of stress
Experimental results taken from bend-cycle fatigue tests comparing base tube samples to skelp-end
welded samples found that the skelp-end weld survival can range from 80 to 90% of the base tube
working life with relatively little variation from one weld to the next. This is well within the typical range of
scatter exhibited by CT fatigue lives tested in the laboratory and the field.
Butt-weld/tube-to-tube weld
A butt-weld or tube-to-tube weld is a means for joining lengths of previously formed tubing. The two ends
of the finished tube to be joined are cut square, slightly beveled, carefully aligned, and TIG- or MIG-
welded (Tungsten inert gas or Metal inert gas) around the circumference. The resulting weld is oriented
perpendicular to the CT axis, focusing the bending stress perpendicular to the tube axis (directly through
the weldment). Because the weld is made from the tubing exterior, the quality of the weld penetration
through the tubing wall is paramount. There are currently two types of tube-to-tube welds in use in CT
services, which are discussed next.
Factory butt-weld
Before the development of the skelp-end weld manufacturing process, all CT strings were constructed by
butt-welding several lengths of finished tubing together using an automated welder at the tubing mill.
These welds were made in carefully controlled conditions, and the quality of these welds was generally
very good. However, these types of welds remain significantly inferior to skelp-end welds, with bend-
cycle fatigue life observed to be in the range of 40% of base pipe working life.
Field butt-weld
Once the CT is delivered to the field location, tubing sections which need to be joined are typically butt-
welded by hand using a TIG or MIG technique. This “field repair” is frequently the only option available at
the service vendor location. Manual butt-welds require a very high level of skill to have acceptable
survival rates. As a result, field butt-welds are the most problematic of all CT welds. With the high
likelihood of significant variations in quality of welds, the recommended practice based on experimental
tests is to derate field butt-welds to approximately 20% of base tube working life.
References
1. ↑ Tipton, S.M. and Newburn, D.A. 1996. Plasticity and Fatigue Damage Modeling of Severly
Loaded Tubing. In Advances in Fatigue Lifetime Predictive Techniques
2. ↑ Tipton, S.M. and Brown, P.A. 1994. Monitoring Coiled Tubing Fatigue Life. Presented at the
International Conference on Coiled Tubing Technology, Houston, Texas, USA, 29-31 March.
3. ↑ Tipton, S.M. 1997. Low-Cycle Fatigue Testing of Coiled Tubing Materials. Presented at the
World Oil Coiled Tubing and Well Intervention Technology Conference, Houston, Texas, USA,
4-6 February.
4. ↑ Walker, E.J. 1990. Collapse Tests Expand Coiled Tubing Uses. Oil Gas J. 88 (10): 56.
5. ↑ Stanley, R.K. 1998. Results From NDE Inspections of Coiled Tubing. Presented at the
SPE/ICoTA Coiled Tubing Roundtable, Houston, Texas, 15-16 March. SPE-46023-
MS. http://dx.doi.org/10.2118/46023-MS.
6. ↑ Tipton, S.M., Moran, D.W., and Sorem, J.R. 2002. Quantifying the Influence of Surface
Defects on Coiled Tubing Fatigue Resistance. Presented at the SPE/ICoTA Coiled Tubing
Conference and Exhibition, Houston, Texas, 9–10 April. SPE-74827-MS.
7. ↑ Moran, D.W., Chinsethagid, C., Sorem, J.R. et al. 2002. Challenges Facing the Development
of Coiled Tubing Inspection Technology. Presented at the SPE/ICoTA Coiled Tubing
Conference and Exhibition, Houston, Texas, 9–10 April. SPE-74835-MS.
Noteworthy papers in OnePetroSisak, W.J. and Crawford, D.J. 1994. The Fatigue Life of Coiled Tubing. Presented at the SPE/IADC
Drilling Conference, Dallas, 15–18 February. SPE-27437-MS. http://dx.doi.org/10.2118/27437-MS
Tipton, S.M., Smalley, E., and VanArnam, D. 2012. Influence of a Straightener on Coiled Tubing Fatigue.
Presented at the SPE/ICoTA Coiled Tubing & Well Intervention Conference and Exhibition, The
Woodlands, Texas, USA, 27–28 March. SPE-154057-MS. http://dx.doi.org/10.2118/154057-MS
Casing and tubing bucklingAs installed, casing usually hangs straight down in vertical wells or lays on the low side of the hole in
deviated wells. Thermal or pressure loads might produce compressive loads, and if these loads are
sufficiently high, the initial configuration will become unstable. However, because the tubing is confined
within open hole or casing, the tubing can deform into another stable configuration, usually a helical or
coil shape in a vertical wellbore or a lateral S-shaped configuration in a deviated hole. These new
equilibrium configurations are what we mean when we talk about buckling in casing design. In contrast,
conventional mechanical engineering design considers buckling in terms of stability (i.e., the prediction of
the critical load at which the original configuration becomes unstable).
AnalysisAccurate analysis of buckling is important for several reasons:
Buckling generates bending stresses not present in the original configuration. If the stresses in the
original configuration were near yield, this additional stress could produce failure, including
permanent plastic deformation called “corkscrewing.”
Buckling causes tubing movement. Coiled tubing is shorter than straight tubing, and this is an
important consideration if the tubing is not fixed.
Tubing buckling causes the relief of compressive axial loads when the both ends of tubing are fixed.
This effect is not as recognized as the first two buckling effects, but is equally important. The axial
compliance of buckled tubing is much less than the compliance of straight tubing. Casing movement,
because of thermal expansion or ballooning, can be accommodated with a lower increase in axial
load for a buckled casing.
The accuracy and comprehensiveness of the buckling model is important for designing tubing. The most
commonly used buckling solution is the model developed by Lubinski in the 1950s. This model is
accurate for vertical wells, but needs modification for deviated wells. Tubing bending stress, because of
buckling, will be overestimated for deviated wells using Lubinski’s formula. However, Lubinski’s solution,
applied to deviated wells, will also overpredict tubing movement. This solution overestimates tubing
compliance, which might greatly underestimate the axial loads, resulting in a nonconservative design.
Casing buckling in oilfield operationsBuckling should be avoided in drilling operations to minimize casing wear. Buckling can be reduced or
eliminated with the following methods:
Applying a pickup force when landing the casing in surface wellhead after cement set
Holding pressure while wait on cement (WOC) to pretension the string
Raising the top of cement
Using centralizers to increasing casing bending stiffness
In production operations, casing buckling is not normally a critical design issue. However, a large amount
of buckling can occur, because of increased production temperatures in some wells. A check should be
made to ensure that plastic deformation or corkscrewing will not occur. This check is possible using
triaxial analysis and including the bending stress because of buckling. Corkscrewing occurs only if the
triaxial stress exceeds the yield strength of the material.
Tubing buckling in oilfield operationsBuckling is typically a more critical design issue for production tubing than for casing. Tubing is typically
exposed to the hottest temperatures during production. Pressure/area effects in floating seal assemblies
can significantly increase buckling. Tubing is less stiff than casing, and annular clearances can be quite
large. Buckling can prevent wireline tools from passing through the tubing. Buckling can be controlled by:
Tubing-to-packer configuration (latched or free, seal bore diameter, allowable movement in seals,
etc.)
Slackoff or pickup force at surface after packer set
Cross-sectional area changes in tubing
Packer fluid density
Tubing stiffness which is influenced by tubing diameter and wall thickness
Centralizers
Hydraulic set pressure for packers
As in casing design, a triaxial check should be made to ensure that plastic deformation or corkscrewing
will not occur.