Experimental Investigation of a Novel, Efficient, and Sustainable Hybrid Silicate System in Oil and Gas Well Cementing

Murtaza, Mobeen; Mahmoud, Mohamed; Tariq, Zeeshan

doi:10.1021/acs.energyfuels.0c01001

Cited by 22 publications

(12 citation statements)

References 37 publications

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“…Sze and Kadir [22] suggested that lead cement slurry should have a minimum compressive strength of 250-300 psi (1.7-2.1 MPa) while tail cement slurry should have a minimum compressive strength of 500 psi (3.4 MPa) after for 24 hours curing period to properly hold casing. Conversely, the most widely cited minimum compressive strength needed before drilling out or support a casing is 500 psi (3.4 MPa) [15,23,24,25]. From Figure 8, all the slurries appeared to have enhanced compressive strength after 12 and 24 hours to structurally hold casings and early drill out.…”

Section: Compressive Strength At 12 and 24 Hoursmentioning

confidence: 99%

Experimental Evaluation of the Performance of Fresh Nano Zeolite as an Oil Well Cement Additive

Broni-Bediako¹,

Naatu²

2021

PSE

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Cementing oil and gas wells require materials that, not only meet performance standards but also fairly different from those encountered in conventional processes. The search for alternative materials for cementing oil wells has increased worldwide. It is desirable that these alternative materials make cement sheath stronger, durable, flexible, cost-effective and more resistant to shocks. This research aimed at evaluating the performance of fresh nano zeolite as an additive for shallow oil well cementing operations. Laboratory tests were conducted on a base cement slurry mixed with different concentrations of fresh nano zeolite from 1% bwoc to 3% bwoc at a Bottomhole Circulating Temperature (BHCT) of 80°F (27°C) to determine physical properties such as compressive strength, thickening time, rheology, free fluid, and fluid loss. The results showed that the compressive strength of the cement slurries improved significantly at 12 hours than 24 hours curing period at 87°F (31°C). As the concentration of fresh nano zeolite increases less time was required to reach 50 psi, 100 psi and most importantly 500 psi which is needed to resume drilling operations. An increase in concentration of fresh nano zeolite at 80°F (27°C) resulted in an increase in the thickening time of all the cement slurries. This shows that fresh nano zeolite has a high retardation effect. Generally, the addition of fresh nano zeolite from 1% bwoc to 3% bwoc improved the carrying capacity of all the cement slurries. Test results also showed that increasing the fresh nano zeolite concentrations resulted in a decrease in rheological values which is a characteristic of a dispersant. Plastic viscosity values were observed to have an increasing trend generally with an increasing concentration of fresh nano zeolites. All the cement slurries were below 100 cP and therefore pumpable. The addition of fresh nano zeolite to the base cement slurry increased the free fluid of the cement slurries. The fresh nano zeolite didn't have any effect on fluid loss and therefore does not exhibit characteristics of a fluid loss agent.

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Section: Compressive Strength At 12 and 24 Hoursmentioning

confidence: 99%

Experimental Evaluation of the Performance of Fresh Nano Zeolite as an Oil Well Cement Additive

Broni-Bediako¹,

Naatu²

2021

PSE

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“…The main objective of the oil well cement is to prevent the movement of fluid between the geological formation and behind the casing string (Murtaza et al 2020;Tariq et al 2020b). A slurry of cement is pumped down into the annulus between the casing and the geological formation.…”

Section: Oil Well Cementingmentioning

confidence: 99%

A systematic review of data science and machine learning applications to the oil and gas industry

Tariq

Aljawad

Hasan

et al. 2021

J Petrol Explor Prod Technol

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101

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This study offered a detailed review of data sciences and machine learning (ML) roles in different petroleum engineering and geosciences segments such as petroleum exploration, reservoir characterization, oil well drilling, production, and well stimulation, emphasizing the newly emerging field of unconventional reservoirs. The future of data science and ML in the oil and gas industry, highlighting what is required from ML for better prediction, is also discussed. This study also provides a comprehensive comparison of different ML techniques used in the oil and gas industry. With the arrival of powerful computers, advanced ML algorithms, and extensive data generation from different industry tools, we see a bright future in developing solutions to the complex problems in the oil and gas industry that were previously beyond the grip of analytical solutions or numerical simulation. ML tools can incorporate every detail in the log data and every information connected to the target data. Despite their limitations, they are not constrained by limiting assumptions of analytical solutions or by particular data and/or power processing requirements of numerical simulators. This detailed and comprehensive study can serve as an exclusive reference for ML applications in the industry. Based on the review conducted, it was found that ML techniques offer a great potential in solving problems in almost all areas of the oil and gas industry involving prediction, classification, and clustering. With the generation of huge data in everyday oil and gas industry activates, machine learning and big data handling techniques are becoming a necessity toward a more efficient industry.

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“…It is related to the ability of the drilling mud to suspend the drill cuttings and, consequently, its capacity to remove them from the wellbore. 75 Figure 7 shows the carrying capacity (YP/PV) values of the base drilling mud and the scavenger-containing drilling muds.…”

Section: H 2 S Scavenging Usingmentioning

confidence: 99%

H₂S Scavenging Capacity and Rheological Properties of Water-Based Drilling Muds

et al. 2020

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Drilling hydrocarbon formations where hydrogen sulfide (H 2 S) is present could lead to the carryover of H 2 S with the drilling mud (i.e., drilling fluid) to the surface, exposing working personnel to this lethal gas. Additionally, H 2 S is very corrosive, causing severe corrosion of metal parts of the drilling equipment, which in turn results in serious operational problems. The addition of an effective H 2 S scavenger(s) in the drilling mud formulations will overcome these health, safety, and operational issues. In this work, zinc oxide (ZnO), which is a common H 2 S scavenger, has been incorporated into waterbased drilling mud. The H 2 S scavenging performance of this ZnOcontaining drilling mud has been assessed. Additionally, drilling mud formulations containing either copper nitrate (Cu(NO 3 ) 2 •3H 2 O) or potassium permanganate (KMnO 4 ) have been prepared, and their H 2 S scavenging performances have been studied and compared to that of the ZnO-containing drilling mud. It has been observed that the scavenging performance (in terms of the H 2 S amounts scavenged up to the breakthrough time and at the saturation condition) of the ZnO-containing drilling mud is very poor compared to those of the copper nitrate-containing and KMnO 4 -containing drilling muds. For instance, the amounts of H 2 S scavenged up to the breakthrough time by ZnO-containing, copper nitrate-containing, and KMnO 4 -containing drilling muds were 5.5, 15.8, and 125.3 mg/g, respectively. Furthermore, the amounts of H 2 S scavenged at the saturation condition by these drilling muds were, respectively, 35.1, 146.8, and 307.5 mg/g, demonstrating the superiority of the KMnO 4 -containing drilling mud. Besides its attractive H 2 S scavenging performance, the KMnO 4 -containing drilling mud possessed more favorable rheological properties [i.e., plastic viscosity (PV), yield point (YP), carrying capacity of the drill cuttings, and gelling characteristics] relative to the base and the ZnO-containing and copper nitrate-containing drilling muds. The addition of KMnO 4 to the base drilling mud increased its apparent viscosity, PV, and YP by 20, 33, and 10%, respectively. Additionally, all tested drilling muds possessed acceptable fluid loss characteristics. To the best of our knowledge, there are so far no published studies concurrently tackling the H 2 S scavenging (i.e., breakthrough time, breakthrough capacity, saturation time, saturation capacity, and scavenger utilization) and the rheological properties of water-based drilling muds, as demonstrated in the current study, highlighting the novelty of this work.

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Experimental Investigation of a Novel, Efficient, and Sustainable Hybrid Silicate System in Oil and Gas Well Cementing

Cited by 22 publications

References 37 publications

Experimental Evaluation of the Performance of Fresh Nano Zeolite as an Oil Well Cement Additive

Experimental Evaluation of the Performance of Fresh Nano Zeolite as an Oil Well Cement Additive

A systematic review of data science and machine learning applications to the oil and gas industry

H₂S Scavenging Capacity and Rheological Properties of Water-Based Drilling Muds

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Experimental Investigation of a Novel, Efficient, and Sustainable Hybrid Silicate System in Oil and Gas Well Cementing

Cited by 22 publications

References 37 publications

Experimental Evaluation of the Performance of Fresh Nano Zeolite as an Oil Well Cement Additive

Experimental Evaluation of the Performance of Fresh Nano Zeolite as an Oil Well Cement Additive

A systematic review of data science and machine learning applications to the oil and gas industry

H2S Scavenging Capacity and Rheological Properties of Water-Based Drilling Muds

Contact Info

Product

Resources

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H₂S Scavenging Capacity and Rheological Properties of Water-Based Drilling Muds