15/01/2019

Chapter 2
Well Servicing

Khafiz Muradov

Institute of Petroleum Engineering, EGIS School, Heriot-Watt University, Edinburgh, U.K.

Learning Objectives

• Explain the need for well servicing and intervention, and their benefits.

• List and describe the equipment and operational concepts involved in wireline, coiled tubing and
hydraulic workover interventions.

• Describe the typical applications of wireline, coiled tubing, and snubbing interventions.

• Describe well pressure control, tool conveyance problems, and safety issues associated with the
different types of well interventions.

• Explain the reasons for and principles of the tubing retrieval.

• Analyse a given well problem and propose the optimal intervention program to rectify it.

• List, locate and describe the measurements routinely taken in wells. Explain their applications.

• Explain the objectives of production logging. Propose the logging tools suitable for these
objectives.

• Describe the production logging tools’ types and measurement principles. Explain how these
measurements are related to the fluid and formation properties as well as to flow phenomena.

1
 15/01/2019

Production Well: A Complex System

Classes of Well Problems

3. Completion
string

2. Wellbore
casing
1. Reservoir &
bottomhole
completion

+ complex (interactive) problems! A->B->C

2
 15/01/2019

Well completion (string) associated problems

Temporary or
permanent

Reasons for Completions Equipment Malfunctions or Failure:

(1) effects of pressure
(2) effects of thermal stress
(3) applied and induced mechanical loadings can cause the tubing to part or
unset packers. They can also be induced by temperature & pressure
changes.
(4) internal corrosion failure due to O2, CO2, H2S and acids. External casing
corrosion can result from corrosive formation waters.
(5) erosion due to high rate flow and/or sand production.

The General Well Completion

Scheme

3
 15/01/2019

The nature and consequence of completion

failure

Example failure events

Well completion problems: vertical lift

performance problems

Depends on the
completion Mechanical or
complexity chemical plugging

Remedial measures:
• Wireline fishing
• Tubing retrieval
• Chemical treatment
• Scraping
vs • Hot wash

4
 15/01/2019

Benefits of well servicing

 Enhancement or restoration of safety

 Reduction in operating costs
 Acceleration of the production revenue
 Increase in the ultimate recovery

Wireline Interventions

Wireline interventions: low cost, fast, operation on live wells possible,

lightweight surface equipment

Typical wireline applications are:

 Well logging.
 Installation of completion equipment prior to running the production
tubing e.g. a packer and a tailpipe assembly.
 Installation or retrieval of equipment within the tubing string e.g. valves,
pressure gauges, etc.
 Operation of downhole equipment to either divert or shut off fluid flow
e.g. open a sliding side door or install a bridge plug.
 Removal of (rather soft) materials, which have built up in the tubing
string, such as wax, debris or sand.
 Well kick-off e.g. by swabbing.
 Adjustment of the completion interval e.g. perforating.

5
 15/01/2019

Basic Wireline Toolstring

Tools and Functions:

 Rope socket: Connection to the
wire (slickline, braided wire, e-line)
 Stem(s) for weight (to lower in live
well and for better jarring effect)
 Jars (mechanical, hydraulic): jolting
effect to shear a pin, latch onto a
device, clean debris, etc.
 Optional knuckle joint for tool
positioning and orientation

Specialist Equipment Examples

Used for:
 checking and cleaning (incl. ‘fishing’ = removing items
blocking the well).
 taking measurements;
 setting, pulling or operating tools

Examples:

a) Gauge Cutter; b) Swage; c) Wireline spear

6
 15/01/2019

Surface Equipment

Key Components:
 Winch
 Hydraulic Power Unit
 Lubricator

Wellhead Equipment

Key Components:
 Lubricator
 Stuffing box
 Wireline BOP
 Bleed-off Valve
 Pulleys

Subsea wells:
 Lubricator extends to surface or
 ROVs / divers or
 Through Flow Line (TFL)
technology
Optional class activity:
 Propose the sequence or RIH or POOH
steps

7
 15/01/2019

Coiled Tubing (CT) Operations

Objectives include:
 Mechanical operations (similar to wireline)
 Circulation operations such as
- well clean-out
- placement of fluids or cement
- kick-off (e.g. via gas lift) or kill the well;
- as a velocity string

 Drilling or milling operations.

 Perforating

Benefits compared to wireline operations:

 Circulation is possible
 Can be used in highly deviated wells (> 65 degrees or so from vertical)
 Can put weight on the tool
 Support heavier equipment

Surface Equipment

Surface equipment:
 A reel of continuous tubing
 A tubing straightener or
gooseneck
 An injector head which will drive
the tubing into the well even if it is
under pressure, as well as
support it
 A stripper (or pack-off) which is a
dynamic seal, and below it:
 A BOP

Bottom hole assembly:

- Nozzles for spotting fluids or
- Drilling tools
- Overshot for latching onto fish
- Etc.

8
 15/01/2019

Snubbing

Equipment:
 A pipe handling system (travelling
and standing jacks with slips)
 A wellhead safety system
consisting of a BOP and a
stripper.
 A hydraulic power unit to drive the
jack(s) and auxiliary pumps.

Hydraulic Workover Mast

Reasons for Tubing Retrieval

 Mechanical failure of the tubing string, for example a leak or collapse of

the tubing

 Inability to conduct tubing wireline equipment replacement through the

internal bore of the string due to ID limitations - small tubing size.

 The necessary replacement of the completion string by an alternative

design, for example to allow the installation of artificial lift.

 The replacement of the tubing string to optimise reservoir performance,

for example to change the tubing string to a smaller size to better
accommodate declining reservoir productivity.

9
 15/01/2019

Data Acquisition in Wells

 At the wellhead:
- Pressure and Temperature (tubing, casing)
- Flowrate (test separator, MPFM)
- Other: erosion, artificial lift, etc.

 In the tubing:
- Tubing wall state (caliper, magnetic field, etc.) – Production Logging
- MPFM
- Other: pump sensor package, fibre-optic, etc.

 At the bottomhole (wellbore):

- Wireline tools, including Production Logging Tools (PLT)
- Gauge cutter
- P and T during testing (flowing, shut-in – well test, multi-rate test, …)
- DST (Drill stem test)
- Other (e.g. geophones or EM surveys)

 Behind tubing or casing:

- Fibre-optic sensors: T, stress, acoustic

Openhole Logging

Many logs describe formation, fluid, and the wellbore state, including
 Sonic
 Spontaneous Potential (SP)
 Gamma Ray (GR)
 Neutron logs
 (Electric) resistivity
 (Magnetic) Induction
 Nuclear Magnetic Resonance
 Caliper
 Formation Imaging
 …

Other measurements:
 Formation Testers

Cased holes: Cement Bond Logging (or similar e.g. Cement Evaluation Tools),
Casing Collar Locator CCL
In cased holes, as part of PL: GR and Neutron can ‘see through’ casing

10
 15/01/2019

Production Logging Objectives

Commonly, PL investigates:

 Status of well completion.

 Anomalous fluid flow between zones.

 Performance of the production or injection interval.

 Success of stimulation treatment.

 Reservoir performance.

Optional class activity:

 Discuss examples of the above

Production Logging Measurements

Fluid velocity measurements

 Routine
 Informative
 Needs calibration
 Sensing envelope

Optional class activity:

 Tutorial 3

11
 15/01/2019

Production Logging Tools

Flowmeters

 Spinner
– Poor performance in multi-phase flow
– Continuous type vs Diverter type
– Multi-pass calibration
– Flow regime - affected

 Downhole MPFMs
– Venturi
– Non-intrusive: reverse, fibre-optic

Virtual flow metering as an option

Production Logging Measurements

Wellbore pressure

 Absolute pressure
– Manometer
– Used for wellbore flow model match, well
testing, PVT corrections

 Pressure gradient
– Gradiometer
– Recognises changes in fluid density –
relates to flowing phases (how?)

VG

VL
Slippage and liquid holdup

12
 15/01/2019

Production Logging Measurements:

Electromagnetic

 Fluid capacitance logging

– Electrodes under oscillating potential (e.g.
radio frequency). Measures fluid
capacitance. Differentiates HC from water

 CCL
– Measures change in magnetic field against
collars. (Alternatively – caliper-type)

 Wall thickness
– Change in electromagnetic field against
thinner tubing (corrosion / erosion?)

Production Logging Measurements: T

Wellbore temperature

 Wellbore thermal state depends on

– Heat convention (examples?)
– Heat conduction (examples?)
– Thermodynamic effects (examples?)

 Situations
– Flowing and shut-in gradients
– Thermal slugs
– Cement hardening

 Can detect
– TOC
– Cross-flow
– Flow behind casing
– Inflow/outflow intervals
– Stimulation assessment

Radial Temperature – flow behind casing

13
 15/01/2019

Production Logging Measurements: Gamma Rays

GR can be either natural or induced by e.g.
(pulsed) neutron bombardment and
‘activation’
Types: Example: gun positioning
 Conventional GR
– Formation props
– Tracers (ejected for V; added for placement allocation)
– Tool positioning

 Spectral GR
– Better differentiation or composition

 Focused GR
– Wellbore fluid density

 Thermal neutron decay

– Formation water saturation

 Pulsed Neutron: activation of elements

– Oxygen for flow behind casing
– Silicon for GP assessment, …

Production Logging Measurements: Acoustic

 Noise
– What makes noise in the well? Does it sound
different for various events?

 Ultrasonic logs
– Small leaks

From ““Production Operations”, Volume 1, by Allen, T., and Roberts, 1997

Optional class activity:
 Propose an example, well performance problem and list the PLTs suitable to detect or even quantify it.

14
 15/01/2019

Fibre-Optic Sensors

 Principle: light back-scattering in an optic fibre. The back scattered light ‘remembers’
the fibre state in the point of scattering

 Interferometer at surface to compare the source, laser pulse spectrum and the back-
scattered one

 Sensing either distributed or discrete (Bragg gratings)

 Can measure continuously: temperature, strain, acoustic signal. MPFM

 Non-intrusive, no electronics downhole

 Problems: ageing, splicing, dry and wet connections

Well Abandonment

 Required by law to ensure there is no fluid spill to surface nor contamination of fresh
water reservoirs by saltwater

 All production/injection and liner hanger (if any) intervals are then cemented. Cement
plugs at least 500’ long with the top of cement at least 100’ above each interval are
placed and tested. Bridge plugs (i.e. mechanical plugs installed permanently e.g. on
a wireline) are installed at the bottom of every next cement plug.

 The near-surface freshwater reservoirs are also cemented.

 Finally, all the surface equipment is removed and the casings are cut a few meters
below surface (or seabed) and retrieved. (Optionally, no casing retrieval from offshore
wells may be required, as long as nothing is protruding above seabed).

15
 15/01/2019

Learning Objectives

• Explain the need for well servicing and intervention, and their benefits.

• List and describe the equipment and operational concepts involved in wireline, coiled tubing and
hydraulic workover interventions.

• Describe the typical applications of wireline, coiled tubing, and snubbing interventions.

• Describe well pressure control, tool conveyance problems, and safety issues associated with the
different types of well interventions.

• Explain the reasons for and principles of the tubing retrieval.

• Analyse a given well problem and propose the optimal intervention program to rectify it.

• List, locate and describe the measurements routinely taken in wells. Explain their applications.

• Explain the objectives of production logging. Propose the logging tools suitable for these
objectives.

• Describe the production logging tools’ types and measurement principles. Explain how these
measurements are related to the fluid and formation properties as well as to flow phenomena.

16