Geothermal Field Development System

Lapangan Panas Bumi Dieng beroperasi sejak tahun 2004 dengan kapasitas turbin 60 MW serta memiliki target produksi sebesar 55 MW selama tigapuluh tahun. Lapangan ini, masih layak untuk dilakukan pengembangan dengan total sebesar 110 MW. Dalam mengoptimalkan kualitas uap (steam quality) dari kepala sumur sampai dengan input turbin maka perlu adanya perencanan mengenai dimensi dari pipa yang mengalirkan uap. Parameter yang diperhatikan dalam perencanaan pipa dua fasa yaitu diameter pipa dan penurunan tekanan. Tujuan penelitian adalah menentukan diameter pipa dua fasa dan penurunan tekanan pada salah satu sumur pengembangan lapangan Panas Bumi Dieng. Metodologi perhitungan dimensi pipa ini menggunakan standar ASME dalam penentuan diameter pipa dan menghitung besarnya penurunan tekanan sebelum input turbin menggunakan software pipesim. Hasil perhitungan salah satu sumur yang memiliki masa aliran sebesar 60 kg/s didapatkan jenis pipa Xtra Strong (XS) kualitas uap 0.176 dengan diameter pipa 8 inchi serta kecepatan aliran yang optimal sebesar 27.33 m/s serta penurunan tekanan dari well head menuju separator adalah 7, 476 bar dengan tekanan input turbin sebesar 22,985 bar.Dieng Geothermal Field operates since 2004 with a 60 MW turbine capacity and has a production target of 55 MW for thirty years. This field is still feasible for development with a total of 110 MW. In optimizing the quality of steam (steam quality) from the wellhead to the turbine input, it is necessary to plan on the dimensions of the pipe that flows steam. Parameters that are considered in planning two-phase pipes are pipe diameter and pressure drop. The research objective was to determine the two-phase pipe diameter and pressure drop at one of the wells in the Dieng Geothermal field development. The methodology for calculating the pipe dimensions uses the ASME standard in determining pipe diameter and calculating the amount of pressure drop before the turbine input using pipesim software. The calculation results of one well that has a flow period of 60 kg / s obtained Xtra Strong (XS) pipe type vapor quality 0.176 with 8 inches pipe diameter and optimal flow velocity of 27.33 m / s and pressure drop from well head to separator is 7 , 476 bars with turbine input pressure of 22,985 bars.

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The features of the geological structure of the Verkhnechonsky oil and gas condensate field and their influence on the field development and operation system

Earth sciences and subsoil use ◽

10.21285/2686-9993-2020-43-3-350-363 ◽

2020 ◽

Vol 43 (3) ◽

pp. 350-363

Author(s):

L. A. Rapatskaya

Keyword(s):

Oil And Gas ◽

Horizontal Wells ◽

Geological Structure ◽

Field Structure ◽

Gas Condensate ◽

Reservoir Properties ◽

Reservoir Water ◽

Horizontal Drilling ◽

Development System ◽

Field Development

The study aims to analyze the relationship between the redetermination of the complexity of the geological structure of the Verkhnechonsky oil and gas condensate field and the schedule adjustment of the field development plans. The paper uses the data on the exploration and production wells obtained from the pilot operation of JSC Verkhnechonskneftegaz, the geophysical work results, and the research materials publicly available in the press. The geological structure of the Verhnechonskoye oil and gas condensate field is unique in its complexity. This is due to the following factors: a combination of tectonic disturbances accompanied by the intrusion of traps; high mineralization of the reservoir water; sharp variability of the filtration and reservoir properties of the producing horizons by area and section due to the unevenness of the lithological composition of the reservoirs, their salinization and complete pinch-out. The development system of any field should take into account the peculiarities of the field’s tectonic and lithological-facies structure, and meet specific technical and economic requirements for drilling and operating wells. The complexity of the field structure requires a thorough selection of a development system that inevitably changes as the features of the field structure are studied, e.g. vertical drilling suggested at the initial stage of the filed development was shortly after replaced with inclined-horizontal drilling with the calculation of two options. Within the pilot operation project of the Verkhnechonsky field, JSC Verkhnechonskneftegaz has developed two variants of uniform grids of directional and horizontal wells with pattern flooding for the most explored deposits of the Verkhnechonsky horizon of blocks I and II. Because of the intensive processes of the reservoirs’ secondary salinization, the flooding method required a study of the reservoir water composition. However, the proposed drilling plan using a downhole engine and gamma-ray logging could not ensure the wellbores ducting through the most productive sections of the horizon, therefore, the flow rates of some directional and horizontal wells were not high enough. To increase the drilling efficiency, the specialists of the Drilling Department (JSC Verhnechonskneftegaz), together with the Department of Geology and Field Development (Schlumberger Ltd.), proposed a new methodology that increases the drilling efficiency by using a rotary-controlled system, logging-while-drilling, and geosteering. Thus, the development system of the Verkhnechonsky oils and gas condensate field was changing in the process of specifying the field’s geological structure, anisotropy reservoir properties, and the thickness of the producing horizons in size and cut, their salinization and pinch-out, and the composition of the reservoir waters.

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The In-situ Stress Field as a Key Issue for Geothermal Field Development – A Case Study from the NE German Basin

71st EAGE Conference and Exhibition incorporating SPE EUROPEC 2009 ◽

10.3997/2214-4609.201400339 ◽

2009 ◽

Cited By ~ 4

Author(s):

I. Moeck ◽

G. Kwiatek ◽

G. Zimmermann

Keyword(s):

Stress Field ◽

In Situ Stress ◽

Geothermal Field ◽

Field Development ◽

In Situ Stress Field ◽

German Basin

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Integrated Approach of Field Development System (Russian)

10.2118/138080-ru ◽

2010 ◽

Author(s):

A. Shoshin ◽

A. Valiev ◽

I. Chuprakov

Keyword(s):

Integrated Approach ◽

Development System ◽

Field Development

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Surface deformation study for a geothermal operation field

Advances in Geosciences ◽

10.5194/adgeo-45-243-2018 ◽

2018 ◽

Vol 45 ◽

pp. 243-249

Author(s):

Wenli Wang ◽

Julia Diessl ◽

Michael S. Bruno

Keyword(s):

Heat Flow ◽

Surface Deformation ◽

Flow Simulation ◽

Ground Level ◽

Geothermal Field ◽

Surface Subsidence ◽

Geomechanical Model ◽

Field Development ◽

Development Plans ◽

The Impact

Abstract. GeoMechanics Technologies has investigated the surface deformation that occurred at a geothermal field operation located in New Zealand. The thermal area associated with this field has extensive surface infrastructures that are in close proximity to a lake. Geothermal operations initially began in 1997 while surface subsidence has been observed since early 2004. We were contracted by the client to review and analyze the impact of future development plans on ground level changes in hopes to mitigate further compaction and subsidence in the area. There is significant concern that continued surface subsidence may cause the lake to flood the surrounding area. An integrated 3-D geological model, geomechanical model, and fluid and heat flow model were developed for this study. To ensure accuracy, a history match and calibration was performed on the geomechanical model using historical subsidence survey data and on the fluid and heat flow simulation using historical injection and production data. The calibrated geomechanical model was then applied to simulate future scenarios to predict surface subsidence and provide a guideline to optimize field development plans.

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