Increasing the efficiency of bactericide use when using seawater in a reservoir pressure maintenance system

Salimat Kh. Bidzhieva; С. Х. Биджиева; Биджиева Салимат Хасановна; Nauruzbek K. Nurseitov; Н. Қ. Нұрсейітов; Нурсеитов Наурузбек Карджаубаевич; Tilektes B. Kalmukhanova; Т. Б. Қалмұханова; Калмуханова Тилектес Багдовлетовна; Maksat S. Utepov; М. С. Өтепов; Утепов Максат Сейлханулы

doi:10.54859/kjogi108660

Increasing the efficiency of bactericide use when using seawater in a reservoir pressure maintenance system

作者: Bidzhieva S.K.¹, Nurseitov N.K.¹, Kalmukhanova T.B.¹, Utepov M.S.¹
隶属关系:
1. Branch of KMG Engineering LLP KazNIPImunaigaz
期: 卷 5, 编号 4 (2023)
页面: 48-59
栏目: Oil and gas field development and exploitation
URL: https://bakhtiniada.ru/2707-4226/article/view/249935
DOI: https://doi.org/10.54859/kjogi108660
ID: 249935

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Rationale: Since 2018, at the Uzen oilfield, in order to study and control the microbiological contamination with sulfate-reducing bacteria (hereinafter referred to as SRB) of oilfield environment, full-scale bactericidal treatment and monitoring of the effectiveness of reagent use have been carried out. At the equipped control points, water samples are taken for the content of SRB cells before and after injection of the bactericide.

Target: Reduce the intensity of sulfidogenesis at the oilfield and, as a consequence, the concentration of hydrogen sulfide in the associated gas.

Materials and methods: Since the applied technology of injecting the bactericide in shock dosages did not allow achieving a stable reduction in the concentration of hydrogen sulfide, it was replaced by the technology of constantly injecting the bactericide into seawater at a dosage of 40 mg/l in an experimental mode. This technology showed low efficiency, hydrogen sulfide (H₂S) concentrations varied between 352–379 ppm, and the monthly consumption of the reagent increased by 40%. Based on the obtained data on ineffectiveness, the constant injection of bactericide at MPS-4 was stopped and a new technology for injection of bactericide was proposed, aimed at suppressing not only planktonic, but also adherent forms of SRB.

Results: Results. Injection of the bactericide using the new technology showed significant efficiency, which was assessed by reducing the concentration of hydrogen sulfide in the associated gas by an average of 45% across the oilfield.

Conclusion: The proposed new technology for injecting a bactericide made it possible to effectively suppress the activity of sulfidogenic microorganisms and reduce the level of biogenic hydrogen sulfide in the oilfield.

关键词

bactericide, hydrogen sulfide, sulfate-reducing bacteria, sulfate reduction, bactericidal treatment

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作者简介

Salimat Bidzhieva

Branch of KMG Engineering LLP KazNIPImunaigaz

编辑信件的主要联系方式.
Email: s.bidzhieva@kmge.kz
ORCID iD: 0000-0002-7599-114X

Cand. Sc. (Biology)

哈萨克斯坦, Aktau

Nauruzbek Nurseitov

Branch of KMG Engineering LLP KazNIPImunaigaz

Email: n.nurseitov@kmge.kz
哈萨克斯坦, Aktau

Tilektes Kalmukhanova

Branch of KMG Engineering LLP KazNIPImunaigaz

Email: t.kalmukhanova@kmge.kz
哈萨克斯坦, Aktau

Maksat Utepov

Branch of KMG Engineering LLP KazNIPImunaigaz

Email: m.utepov@kmge.kz
哈萨克斯坦, Aktau

参考

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Magot M, Ravot G, Campaignolle X, et al. Dethiosulfovibrio peptidovorans gen. nov., sp. nov., a new anaerobic, slightly halophilic, thiosulfate-reducing bacterium from corroding offshore oil wells. Int J Syst Bacteriol. 1997;47(3):818–824. doi: 10.1099/00207713-47-3-818.
Liamleam W, Annachhatre AP. Electron donors for biological sulfate reduction. Biotechnol Adv. 2007;25(5):452–463. doi: 10.1016/j.biotechadv.2007.05.002.
Khatib ZI, Salanitro JR. Reservoir souring: analysis of surveys and experience in sour waterfloods // Society of Petroleum Engineers; 1997 Oct 5–8; San Antonio, Texas. Available from: https://onepetro.org/SPEATCE/proceedings-abstract/97SPE/All-97SPE/SPE-38795-MS/189127.
Holubnyak YI, Bremer JM, Mibeck BAF, et al. Understanding the souring at Bakken oil reservoirs // Society of Petroleum Engineers; 2011 Apr 11–13; The Woodlands, Texas, USA. Available from: https://onepetro.org/SPEOCC/proceedings-abstract/11OCS/All-11OCS/SPE-141434-MS/151097.
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Sokolova DS, Semenova EM, Grouzdev DS, et al. Sulfidogenic microbial communities of the Uzen high-temperature oil field in Kazakhstan. Microorganisms. 2021;9(9):1818. doi: 10.3390/microorganisms 9091818.
Imanbayev BA, Zhaparov NS, Maksut DM, Utepov MS. Methods of combating biogenic hydrogen sul- fur at the Uzen and Karamandibas oilfield. Kazakhstan journal for oil & gas industry. 2021;4(9):79–92. (In Russ).
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Mullaev BT, Abitova AZ, Sayenko OB, Turikpenbayev BZ. Uzen field. Problems and solutions. Almaty: Nur-Print; 2016. (In Russ).

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2. Figure 1. Effective suppression of the SRB development as a result of the use of recirculating bactericidal treatment on MPS -4 RCT №1 и 2.

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3. Figure 2. Map of waste, mixed and sea water injection zones at the Uzen oilfield and distribution of hydrogen sulfide content (as of March 2023)

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4. Figure 3. Dynamics of reagent consumption and hydrogen sulfide content in associated gas for all gas plants (average value) for the period from January to May 2023

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5. Figure 4. Hydrogen sulfide contamination distribution maps for 2023

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