Improving Gas Well Drilling and Completion with High Energy Lasers
Brian C. Gahan Gas Technology Institute
1 Drilling for Oil and Gas in the US
Oil and Gas Wells Drilled, 1985-2000 Exploratory and Development
350 80 Total Footage Drilled (Oil, Gas, & 70 300 Dry Holes)
Petroleum Total Wells Completed d d 60 250 ) ille t r ille e r 50 e D 000)
D 200 ( F 40 lls e ge of ear a s t 150 Y n l W
30 r a e t P o
illio 100 l Foo 20 a M T t ( 50 To 10
0 0 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 00
2 Drilling for Oil and Gas in the US
140 7000
120 6000
100 5000
80 Average Depth per Well 4000 pth (ft) De 60 Dollars per Foot 3000
Average Cost per Foot 40 Estimated Cost Per Foot and Average 2000 Depth Per Well of All Wells (Oil, Gas and Dry) Drilled Onshore in 20 the U.S. from 1959 - 1999 1000 (DeGolyer and MacNaughton, 2000)
0 0 1959 1964 1969 1974 1979 1984 1989 1994
Year 3 Drilling for Oil and Gas in the US
! 1990 GRI Study on Drilling Costs
Major Categories % of Total Time Making Hole 48
Changing Bits 27 And Steel Casing Well & Formation Characteristics 25
Total Drilling Time 100% .
4 High-energy Laser Applications
Lasers could play a significant role as a vertical boring & perforating tool in gas well drilling
5 System Vision
! Laser on surface or within drilling tubing applies infrared energy to the working face of the borehole. ! The downhole assembly includes sensors that measure standard geophysical formation information, as well as imaging of the borehole wall, all in real time. ! Excavated material is circulated to the surface as solid particles
6 System Vision
! When desired, some or all of the excavated material is melted and forced into and against the wall rock. ! The ceramic thus formed can replace the steel casing currently used to line well bores to stabilize the well and to control abnormal pressures.
7 System Vision
! When the well bore reaches its target depth, the well is completed by using the same laser emergy to perforate through the ceramic casing. ! All this is done in one pass without removing the drill string from the hole.
8 Laser Product Development
LASER BASIC RESEARCH
Laser FE Laser Perf Laser Drilling Assist
9 Off Ramp: Perforating Tool
! Proposal Submitted to Service Industry Partner ! Purpose – Complete or re-complete existing well using laser energy ! Requirements – Durable, reliable laser system – Energy delivery system – Purpose designed downhole assembly
10 Preliminary Feasibility Study
! Laser Drilling Experiments – 11/97 – Basic Research – 2 years ! Three High-Powered Military Lasers – Chemical Oxygen Iodine Laser (COIL) – Mid Infra-Red Advanced Chemical Laser (MIRACL)
– CO2 Laser ! Various Rock Types Studied – Sandstone, Limestone, Shale – Granite, Concrete, Salt
11 MIRACL – Simulated Perf Shot
A two-inch laser beam is sent to the side of a sandstone sample to simulate a horizontal drilling application.
12 MIRACL – Simulated Borehole Shot
After a four-second exposure to the beam, a hole is blasted through the sandstone sample, removing six pounds of material.
13 GRI-Funded Study Conclusions
! Previous Literature Overestimated SE ! Existing Lasers Able to Penetrate All Rock ! Laser/Rock Interactions Are a Function of Rock and Laser (Spall, Melt or Vaporize) ! Secondary Effects Reduce Destruction ! Melt Sheaths Similar to Ceramic
Study Conclusions Indicate Additional Research is Warranted
14 Laser Drilling Team – Phase I
Gas Technology Institute DOE NETL Argonne National Laboratory Colorado School of Mines Parker Geoscience Consulting Halliburton Energy Services PDVSA-Intevep, S.A
15 Drilling With The Power Of Light
! DOE Cooperative Agreement DE-FC26-00NT40917 – Original Proposed Tasks and Timeline
TABLE 3: WORK TASK TIMELINES 2000 2001 2002 2003 Quarter341234123412 Year 1 Year 2 Year 3 Quarter123412341234 Task 1. Project Structure and Management Task 2. Fundamental Research 2.1 Laser cutting energy assessment series 2.2 Variable Pulse Laser Effects 2.3 Drilling Under Insitu Conditions 2.4 Rock-Melt Lining Stability 2.5 Gas Storage Stimulation 2.6 Laser Induced Rock Fracturing Model 2.7 Laser Drilling Engineering Issue Identification Task 3. System Design Integration 3.1 Solids Control 3.2 Pressure Control 3.3 Bottom-hole Assembly 3.4 High Energy Transmission 3.5 Completion and Stimulation Techniques for Gas Well Drilling 3.6 Completion and Stimulation Techniques for Gas Storage Wells Task 4. Data Synthesis and Interpretation Task 5. Integration and Reporting Task 6. Milestones Task 7.Technology Transfer 16 First Phase (FY-01) Objectives
! Accepted Phase 1 Task List 1. Laser cutting energy assessment 2. Variable pulse laser effects (Nd:YAG) 3. Lasing through liquids
TABLE 3: WORK TASK TIMELINES 2000 2001 Quarter 4 1 2 3 Year 1 Quarter 1 2 3 4 1.0 Project Structure and Management
1.1 Laser cutting energy assessment series 1.2 Variable Pulse Laser Effects 1.3 Conduct Lasing Through Liquids 1.4 Topical Report
17 Phase I Laser: 1.6 kW Nd:YAG Neodymium Yttrium Aluminum Garnet (Nd:YAG)
Focusing Optics Coaxial Gas Purge Laser Beam
1.27 cm Rock
7.6 cm
18 Conclusions: GTI/DOE Phase I
! SE for Shale 10x Less Than SS or LS ! Pulsed Lasers Cut Faster & With Less Energy Than Continuous Wave Lasers. ! Fluid Saturated Rocks Cut Faster Than Dry Rocks. ! Possible Mechanisms Include: ! More Rapid Heat Transfer Away From the Cutting Face Suppressing Melting ! Steam Expansion of Water ! Contributing to Spallation 19 Conclusions: GTI/DOE Phase I
! Optimal Laser Parameters Observed to Minimize SE for Each Rock Type ! Shorter Total Duration Pulses Reduce Secondary Effects from Heat Accumulation ! Rethink Laser Application Theory – Rate of Application: Blasting vs Chipping ! Unlimited Downhole Applications Possible due to Precision and Control (i.e., direction, power, etc.)
20 DOE-GTI/NGOTP-ANL Phase 2 In Progress
! Continuation of SE Investigations – Effects at In-Situ Conditions – Effects of Multiple Bursts and Relaxation Time – Observations at Melt/Vapor Boundary
21 Supporting Slides Detailing Phase I Work
22 Laser Cutting Energy Assessment
! Measure specific energy (SE) – Limitation of variables • SS, shale and LS samples • Minimize secondary effects – Identify laser-rock interaction mechanisms (zones) • Spall, melt, vaporize
23 Just Enough Power
! Conducted Linear Tests – Constant Velocity Beam Application (dx) – Constant Velocity Focal Change (dz) ! Five Zones Defined in Linear Tests ! Identified Zones Judged Desirable for Rapid Material Removal – Boundary Parameters Determined for Spall into Melt Conditions
24 Laser/Rock Interaction Zones
! Zone Called Thermal Spallation Judged Desirable for Rapid Material Removal ! Optimal Laser Parameters Were Determined to Minimize: – Melting – Specific Energy (SE) Values – Other Energy Absorbing Secondary Effects, and – Maximize Rock Removal ! Short Beam Pulses Provided “Chipping” Mechanism Comparable to Conventional Mechanical Methods
25 Zonal Differences
! SE differs greatly between zones ! Shale shows clear SE change between melt/no melt zones ! Much analysis remains to understand sensitivities of different variables
26 SE vs Measured Average Power (kW) 6 SH11A
5 cc) Spallation Zone 3 - Significant Melt 4 (kJ/ y SH10 g er 3 SH11B2
En SH18A SH13A c i 2 SH11B1 f 2 R = 0.9095 SH12B2 SH15A2 SH2 SH12B1 SH6 eci SH15A1
Sp 1 Zone 2 - No Melt SH8 Minimum SE 0 0 0.2 0.4 0.6 0.8 1 1.2 1.4 Measured Average Power (kW)
27 Lithology Differences
! Differences between lithologies more pronounced when secondary effects minimized ! Shale has lowest SE by an order of magnitude. ! Sandstone and limestone remain similar, as in CW tests
28 All ND:YAG Tests 10000
1000 Sandstone Limestone Shale kJ/cc y g 100 er n
10 c E i
ecif 1 p S
0 0 200 400 600 800 1000 1200 1400 Average Power W
29 SE Values: Wet vs. Dry Samples
35
30 ) cc
/ 25 J k
( Dry y
g 20 er n E
c 15 i f eci
p 10 S Wet 5
0 00.51 Power (kW) Dry rock samples Dry rock samples Water-saturated samples
Atmospheric Conditions
30 .