Deep Underground Injection of Waste from Drilling Activities—An Overview
Abstract
:1. Introduction
2. Overview of Oil and Gas Exploration and Production Waste Disposal Methods
3. History of the Drilling Waste Underground Injection
- To secure injected waste containment within the desired formation (environmental management).
- To maintain maximum injectivity during the implementation of the project with minimum well workover intervention (cost management).
- To maximize formation storage capacity and well life (asset management).
4. Injection Methods and Equipment
4.1. Selection of the Appropriate Waste Injection Method
4.1.1. Annular Injection of Drilling Waste
4.1.2. Tubular Injection of Drilling Waste
4.2. Waste Slurry Preparation and Disposal Unit
5. Waste Slurry
6. Criteria for the Injection Zone Selection and Characterization
7. Disposal Domain Characterization during the Planning and Executing Phase of Underground Waste Disposal
- increasing the local in-situ stress as a result of filling the formation with injected material.
- thermal alteration of the local stress as a result of temperature dilatation during and after waste injection. These alterations are consequences of cold slurry injection within subsurface formations with certain constant temperatures.
- In-situ local stress changes as the result of a pore pressure increase and poro-elastic effect.
8. Injection Well Integrity
9. Injection Process Monitoring
10. Abandonment and Plugging of Injection Wells
11. Discussion and Conclusions Remarks
Author Contributions
Funding
Conflicts of Interest
References
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Type of Waste | Main Components | Possible Environmentally Significant Constituents |
---|---|---|
Waste lubricants | Lube oil, grase | Heavy metals, organics |
Spacers | Mineral oil, detergents, surfactants | Hydrocarbon, alcohol, aromatics |
Spent/contaminated water-based muds (include brine) | Whole mud, mineral oil, biodegradable matters | Heavy metals, inorganic salts, biocides, hydrocarbons, solids/cuttings, organics |
Waste-based mud cuttings | Formation solids, water-based muds, mineral oil | Heavy metals, inorganic salts, biocides, hydrocarbons, solids/cuttings |
Spent/contaminated oil-based muds | Whole-mud mineral oils | Hydrocarbons, heavy metals, inorganic salts, solids, organics, surfactants |
Oil-based mud cuttings | Formation solids, oil-based muds | Heavy metals, inorganic salt, hydrocarbons, solids/cuttings |
Spent bulk chemical | Cement, bentonite, barite, viscosifiers, thinners, fluid loss reducers, special products | Heavy metals, hydrocarbon, organics, solids |
Spent special products | H2S scavengers, defoamers, tracers | Zinc carbonates, iron oxides, hydrocarbons, silicon oils, potassium salts, radioactive materials |
Comparison Factor | Fixation | Thermal Treatment | Drilling Cuttings Reinjection | Bioremediation/Composting |
---|---|---|---|---|
Environmental impact | Low | High | Low | Medium |
Cost | $57–63 per m3 | $90 per metric ton (or $80 per m3 for oil-specific gravity 0.88) | $31 per m3 | $500 per m3 |
Cost factor | May require transport and liner and requires monitoring | Requires transport; air emission control | More expensive if dedicated well(s) are required | May require transport and required monitoring |
Safety risks | High | High | Low | Medium |
Technical feasibility | Low | Medium | High | Medium |
Liability | Liability may be long-term if there are subsequent problems with liner, etc. | Little liability apart from substances like heavy metals remaining in the cleaned material | Little liability if performed correctly | Short-term liability while material is treated during biotreatment, or possible long-term liability if there is subsequent degradation of stabilized material (spreading) |
Reference | Waste Slurry Preparation | Properties of the Injected Waste Slurry | |||
---|---|---|---|---|---|
Type of Solid Waste | Particle Concentration (by % of Volume) | Injected Volume (m3) | Density (kg/m3) | ||
Mahrous et al. [59] | N/A | Drilled cuttings and discharged mud | 10–20 | 95,867 | 1000–1200 |
Mohamed et al. [60] | N/A | Waste from oil and gas production | 10–23 | N/A | N/A |
Organic municipal waste | 10–12 | ||||
Waste from oil and gas production | 5–12 | ||||
Guo et al. [61] | N/A | N/A | up to 20 | N/A | N/A |
Romero et al. [62] | Grinding of cuttings up to particle diameter less than 175 µm and mixing with produced water | Drilled cuttings, discharged mud and waste water | up to 20 | 33,231 | 1008–1272 |
Mehtar et al. [63] | Grinding of cuttings up to particle diameter less than 300 µm and mixing with sea water and liquid waste | Drilled cuttings, discharged mud, slop and sea water | 15–20 | 80,000 | 1200–1400 |
Xia et al. [64] | Using of sea water for waste slurry preparation | Drilled cuttings, water-based and oil-based mud, cleaning water | 10–25 | 168,436 | 1200–1250 |
Kunze et al. [65] | Mixture of drilled cuttings and produced water, removing of the particles with low dispersibility | Drilled cuttings, water-based mud and produced water | 21 | 5928 | 1320 |
Fetsenets et al. [50] | Grinding of cuttings and mixing with water | Drilled cuttings, discharged mud and waste water | N/A | 79,182 | N/A |
Gumarov et al. [33] | N/A | Drilled cuttings and discharged mud | 20 | 160,000 | N/A |
Ovalle et al. [66] | N/A | Drilling waste from reservoir pit | N/A | 11,766 | N/A |
Arfie et al. [10] | Mixture of drilled cuttings and produced water | Viscous oily fluids (oil, sand and water emulsions) | 10–33 | 1,033,000 | N/A |
Reed et al. [67] | Mixture of waste and produced water | Drilled cuttings, produced sand, produced water, crude oil (with low portion of NORM) | 20–70 | 469,002 | N/A |
Sipple-Srinivasan et al. [68] | Grinding of contaminated soil and mixing with water | Contaminated soil (with high portions of clay) and discharged mud | 10–35 | 2290 | N/A |
Sipple-Srinivasan et al. [21] | Mixing of waste with produced water | Oily residue from bottom of the tanks | N/A | 45,000 | 1150–1210 |
Dusseault et al. [37] | Slop diluted with doubled volume of the produced water | Slop | <3 | 3911 | 1020–1080 |
Moschovidis et al. [69] | Grinding of cuttings up to particle diameters less than 400 µm and mixing with sea water | Fluid (usually water) used for rinsing of oily cuttings | 4 | >19,080 | ≈1200 |
Drilled cuttings, seawater and 2% of oil | 22 | ≈54,060 | |||
Minton and Secoy [48] | Grinding of oily cuttings up to particle diameters less than 300 µm and mixing with sea water | Oily drilled cuttings | N/A | N/A | N/A |
Willson et al. [70] | Grinding of cuttings and mixing with sea water | Oil-based mud, oily drill cuttings | ≈15 | 22,187 | 1170–1430 |
Abou-Sayed et al. [71] | N/A | Waste crude oil, acids, unused proppant, discharged mud, residue from bottom of the tanks | N/A | 318,000 | N/A |
Reference | Duration of Waste Injection | Type of Injection | Way of Injection | Injection Pressure (MPa) | Flow Rate (m3 per Day) |
---|---|---|---|---|---|
Mahrous et al. [59] | 14 mounts | Tubing injection | N/A | Maximum 34.5 | N/A |
Mohamed et al. [60] | January 2012–December 2015 | Tubing injection | Intermittent (batch volume 16–480 m3) | 6.9 | 900–1150 |
December 2015–June 2017 | Intermittent (batch volume 1270–1590 m3) | 19 | 1800–2300 | ||
January 2012–March 2018 | Intermittent (batch volume 795–1590 m3) | 9.5 | 2300–2750 | ||
Guo et al. [61] | 10 February 2016–25 January 2017 | Tubing injection | Intermittent (12 h of batch slurry injection) with water flushing before and after injection | 10.3–16.7 | Maximum 2750 |
Romero et al. [62] | June 2014–December 2015 | Tubing injection | Intermittent (12 h of batch slurry injection) with water flushing before and after injection | 12.4–13.8 | 916 |
Mehtar et al. [63] | N/A | Tubing injection | Intermittent (batch volume 48 m3) with maximum 4 h delay between two batches of slurry injection | 10.7–11.2 | 1150 |
Xia et al. [64] | February 2012–April 2014 | Tubing injection | Intermittent, with 3–4 h delay between two batches of slurry injection and flushing with sea water before and after injection | 17.2 | 1603 |
Kunze et al. [65] | 13 October 2010–31 March 2011 | Tubing injection | Intermittent (18 h of batch slurry injection) with injection of 0.8 m3 of viscous pill before waste slurry injection and 16 m3 water after injection | 3.2–5.6 | 1227–1479 |
Fetsenets et al. [50] | October 2008–July 2009 | Tubing injection | N/A | 12 | 318 |
Gumarov et al. [33] | January 2008–August 2008 | Tubing injection | Intermittent and flushing with water (1.5 × tubing capacity) after injection to prevent cuttings settling | 22.8–33.1 | up to 1150 |
November 2007–January 2008 | 15.2–26.9 | N/A | |||
June 2008–November 2008 | 15.2–31.7 | up to 1360 | |||
Ovalle et al. [66] | N/A | Tubing injection | N/A | Maximum 12.1 | N/A |
Arfie et al. [10] | December 2002–March 2005 | N/A | Intermittent (duration of injection 9–10 h per day) with 14 h delay between two batches of slurry injection | 5.5 | N/A |
Reed et al. [67] | November 1997–May 1998 | Tubing injection | Intermittent (duration of injection 9–11 h) with 13–15 h delay between two batches of slurry injection | 24.7–27.2 | 1832–3663 |
June 1998–March 2000 | 23.1–25.5 | ||||
Sipple-Srinivasan et al. [68] | 31 August 1997–21 September 1997 | Tubing injection | Intermittent (duration of injection 6–8 h) with 12 h delay between two batches of slurry injection and 2 h of flushing with water | N/A | 2290–2748 |
Sipple-Srinivasan et al. [21] | 30 December 1996–14 April 1997 | tubing injection | N/A | N/A | 1584–2160 |
Dusseault et al. [37] | 22 April 1996–15 May 1996 | Tubing injection | Intermittent (duration of injection 12 h) with 10 h delay between two batches of slurry injection and 2 h of flushing with water | 8 | 57.6 |
23 May 1996–11 September 1996 | |||||
Moschovidis et al. [69] | 1 January 1990–13 January 1992 | Tubing injection | Intermittent (more than 100 batches with volume 160–480 m3) | Maximum 31 | N/A |
January 1992–December 1993 | Maximum 28.3 | ||||
Minton and Secoy [48] | N/A | Annular injection | Intermittent (only three batches injected) | 5.2 | 570–900 |
Willson et al. [70] | 30 July 1991–5 November 1992 | Annular injection | Intermittent (batch volume 32–64 m3) | 6.2–11 | 870–2518.6 |
Abou-Sayed et al. [71] | N/A | Tubing injection | Intermittent | Maximum 9.7 | 916–1832 |
Parameter | Value of Parameter |
---|---|
Reservoir thickness | More than 2 m |
Cap rock thickness | 4 times higher than reservoir thickness |
Permeability | Between 10 × 10−3 µm2 and 10,000 × 10−3 µm2 |
Reservoir depth | Between 200 and 3000 m |
Structural setup | Intermediate or simple |
Sand-shale sequence | Few layers |
Geological Criteria | Environmental Criteria | ||
---|---|---|---|
Parameter | Value of Parameter | Parameter | Value of Parameter |
Reservoir thickness | More than 5 m | Economic value of formation | Low |
Cap rock thickness | More than 10 m | Urban/industrial development | Far |
Permeability | from 10 × 10−3 µm2 to 1000 × 10−3 µm2 | Impact on vegetation | Nil—minimal |
Porosity | More than 15% | Micro-climatic impact | Reduction in temperature |
Reservoir depth | Between 200 and 3000 m | Land use/landcover | Reclamation |
Structural complexity | Undeformed or simple | Micro-elevation changes | Infinitesimal |
Lithology | Intercalated sand-shale | Transportation | Short distance |
Reservoir strength | Intermediate–weak | - | - |
Groundwater source | No source nearby | - | - |
Reference | Service Company | Location | Characteristic of the Disposal Formation | ||||||
---|---|---|---|---|---|---|---|---|---|
Type of Rock | Depth (m) | Permeability (μm2) | Porosity (-) | Formation Fracture Pressure Gradient (kPa/m) | Depth of Perforation or Annular Injection (m) | Cap Rock | |||
Mahrous et al. [59] | Halliburton | Sakhalin, Russia | N/A | N/A | N/A | N/A | N/A | N/A | N/A |
Mohamed et al. [60] | Advantek Waste Management Services | N/A | Sandstone | 1670–1710 | 0.35–3.5 | 0.25 | 10.1 | N/A | N/A |
1380–1460 | 0.3–0.5 | 0.26 | 10.1 | ||||||
1900–1950 | 0.05–0.1 | 0.17 | 9.1 | ||||||
Guo et al. [61] | Advantek Waste Management Services | Texas, USA | Sandstone interbedded with shale | 1950–2030 | 0.0001–0.105 | 0.185–0.259 | 17.2–18.1 | N/A | Tick shale layer |
Romero et al. [62] | Halliburton/Petroamazonas | Apaika-Nenke Field, Ekvador | N/A | N/A | N/A | N/A | 12.9 | N/A | N/A |
Mehtar et al. [63] | M-I Swaco | Abu Dhabi, UAE | Limestone | 1315–1390 | N/A | N/A | 17.7–19 | N/A | Dolomite and limestone |
Xia et al. [64] | Terralog Technologies Inc., Saudi Aramco | Manifa, Saudi Arabia | Sandstone | 1827–1994 (MD) | 2.24 | 0.24 | N/A | 1981–1990 | Shale and sandstone alteration |
Kunze et al. [65] | ExxonMobil | Colorado, USA | Sandstone | 1684–1752 (MD) | N/A | N/A | N/A | 1710–1725 | N/A |
Fetsenets et al. [50] | Gazpromneft- Khantos/M-I Swaco | Western Sibir, Russia | N/A | ≈1300 and 1700 | N/A | N/A | N/A | N/A | N/A |
Gumarov et al. [33] | M-I Swaco | Caspian Sea | Mudstone | N/A | N/A | N/A | N/A | N/A | N/A |
Ovalle et al. [66] | M-I Swaco | South America | Sandstone | 1401 | N/A | N/A | N/A | 1401–1408 | Limestone |
Arfie et al. [10] | Terralog Technologies Inc. | Duri, Indonesia | Unconsolidated sandstone | 383 | N/A | N/A | N/A | 380–389 | Shale |
418 | 419–430 | ||||||||
Reed et al. [67] | Chevron | Louisiana, USA | Sandstone | 1341–1524 | 0.5–2.0 | 0.23 | 16.5–18.1 | 1512–1524 | Shale and sand alteration (thickness of the layers 3–45 m) |
17.4–19.5 | 1378–1390 | ||||||||
Sipple-Srinivasan et al. [68] | Terralog Technologies Inc. | West Coyote, California | Depleted oil reservoir | 1250 | 0.5 | 0.3 | 5.2 | 1237–1264 | Shale (969–1189 m) |
Sipple-Srinivasan et al. [21] | Terralog Technologies Inc. | Saskatchewan, Canada | N/A | N/A | N/A | N/A | N/A | N/A | N/A |
Dusseault et al. [37] | Terralog Technologies Inc. | Alberta, Canada | Sandstone | 732–752 | 0.5 | 0.27 | 17.5–19.5 | 745.5–748.5 | Low permeability shale (454–717 m) |
Moschovidis et al. [69] | Amoco | Valhall, The North Sea | Siltite (shale) | 2395 | N/A | N/A | ≈13.6 | N/A | Shale |
2467 | |||||||||
Minton and Secoy [48] | BP Exploration Operating Co. | Offshore platform Clyde, The North Sea | Shale | 760–1720 | N/A | N/A | N/A | 760 | N/A |
Willson et al. [70] | BP Norway | Offshore platform Gyda, The North Sea | Mudstone (shale) | 900 | N/A | N/A | 10.2 | 900 | Sandstone interbedded with shale (250–400 m) |
Abou-Sayed et al. [71] | ARCO Oil & Gas Inc. | Prudhoe Bay, Alaska | Sandstone and gravel | ≈650 | 1–2 | N/A | 18.5–19.2 | N/A | 30 m of shale and permafrost up to surface |
Per Well Site | Stimulation (Hydraulic Fracturing) | Waste Injection (Above Formation Fracturing Pressure) |
---|---|---|
Batch volume (m3) | 160–800 | 8000–800,000 |
Injection rate (m3/s) | 0.0265–0.265 | 0.00265–0.053 |
Treatment time | Hours | Weeks, months or years |
Fluid type | Crosslinked guar | Bentonite mud, xanthan gum |
Viscosity (P·s) | 0.2 | 0.002–0.08 |
Solid type and size (m) | Proppant (1680 × 10−6/1000 × 10−6–841 × 10−6/420 × 10−6) or (12/18–20/40 mesh) | Cutting (less than 300 × 10−6 m) or (less than 40 mesh proppant) |
Concentration (vol%) | 10–30 | Most <10 |
Alternatives | Advantage | Disadvantage |
---|---|---|
Set time period for renewing operations or abandoning | Reduces potential for operator’s economic loss; assures eventual closing by setting plugging date; can supplement reporting, testing or monitoring requirements | Imposes higher surveillance workload than immediate abandonment; marginally increases possibility of improper abandonment |
Mechanical integrity test | Identifies well deterioration, which requires immediate abandonment; can supplement other alternatives; reduces potential for economic loss | Requires periodic testing, which may impose significant cost; increases the likelihood of improper abandonment if not accompanied by specific abandonment date |
Self-reporting | Keeps agency informed of well location, ownership and status; reduces potential for economic loss; can supplement other alternatives | Increases regulatory agency surveillance workload; increases likelihood of improper abandonment |
Monitoring of water level or aquifer | Can provide useful scientific data; reduces potential for loss of recoverable energy or minerals | Can be costly, does not provide data on environmental impacts of improper abandonment; creates burdensome surveillance workload; increases likelihood of improper abandonment |
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Gaurina-Međimurec, N.; Pašić, B.; Mijić, P.; Medved, I. Deep Underground Injection of Waste from Drilling Activities—An Overview. Minerals 2020, 10, 303. https://doi.org/10.3390/min10040303
Gaurina-Međimurec N, Pašić B, Mijić P, Medved I. Deep Underground Injection of Waste from Drilling Activities—An Overview. Minerals. 2020; 10(4):303. https://doi.org/10.3390/min10040303
Chicago/Turabian StyleGaurina-Međimurec, Nediljka, Borivoje Pašić, Petar Mijić, and Igor Medved. 2020. "Deep Underground Injection of Waste from Drilling Activities—An Overview" Minerals 10, no. 4: 303. https://doi.org/10.3390/min10040303
APA StyleGaurina-Međimurec, N., Pašić, B., Mijić, P., & Medved, I. (2020). Deep Underground Injection of Waste from Drilling Activities—An Overview. Minerals, 10(4), 303. https://doi.org/10.3390/min10040303