Analysis of Sandbody Development Model in Lishui Depression

To a certain extent, the development of sand body in lishui depression determines the success of oil and gas exploration, so the development models of sand body become the focus of current research. Based on seismic interpretation and exploration practice, five types of sand body development model were developed in lishui depression, including gentle slope-valley typed sand control model, steep slope-valley typed sand control model, trough fault controlling axial typed sand control model, gentle slope -contemporaneous fault typed sand control model and bulge steep slope-cross section typed sand control model.Different sand body development model determines the development characteristics of sand body and indicates the direction of exploration.

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High-resolution seismic processing technique with broadband,wide-azimuth, and high-density seismic data - A case study of thin-sand reservoir in eastern China

Interpretation ◽

10.1190/int-2020-0107.1 ◽

2021 ◽

pp. 1-45

Author(s):

Qin Su ◽

Huahui Zeng ◽

Yancan Tian ◽

HaiLiang Li ◽

Lei Lyu ◽

...

Keyword(s):

Seismic Data ◽

Oil And Gas ◽

Single Point ◽

Eastern China ◽

High Density ◽

Songliao Basin ◽

Seismic Processing ◽

Oil And Gas Exploration ◽

Sand Body

Seismic processing and interpretation techniques provide important tools for the oil and gas exploration of the Songliao Basin in eastern China, which is dominated by terrestrial facies. In the Songliao Basin, a large number of thin-sand reservoirs are widely distributed, which are the primary targets of potential oil and gas exploration and exploitation. An important job of the exploration in the Songliao Basin is to accurately describe the distribution of these thin-sand belts and the sand-body shapes. However, the thickness of these thin-sand reservoirs are generally below the resolution of the conventional seismic processing. Most of the reservoirs are thin-interbeds of sand and mudstones with strong vertical and lateral variations. This makes it difficult to accurately predict the vertical and horizontal distribution of the thin-sand bodies using the conventional seismic processing and interpretation methods. Additionally, these lithologic traps are difficult to identify due to the complex controlling factor and distribution characteristics, and strong concealment. These challenges motivate us to improve the seismic data quality to help delineate the thin-sand reservoirs. In this paper, we use the broadband, wide-azimuth, and high-density integrated seismic exploration technique to help delineate the thin-reservoirs. We first use field single-point excitation and single-point receiver acquisition to obtain seismic data with wide frequency-bands, wide-azimuth angles, and high folds, which contain rich geological information. Next, we perform the near-surface Q-compensation, viscoelastic prestack time migration, seismic attributes, and seismic waveform indication inversion on the new acquired seismic data. The 3D case study indicates the benefits of improving the imaging of thin-sand body and the accuracy of inversion and reservoir characterization using the method in this paper.

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Hydrocarbon Accumulation Conditions and Reservoir Characteriscs of Shahejie Formation in Tangzhuang Area

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.734-737.1391 ◽

2013 ◽

Vol 734-737 ◽

pp. 1391-1394

Author(s):

Ming Jian Wang ◽

Xun Hua Zhang

Keyword(s):

Source Rock ◽

Central Region ◽

Oil And Gas ◽

Geophysical Data ◽

Hydrocarbon Generation ◽

Hydrocarbon Accumulation ◽

Dominant Type ◽

Oil And Gas Exploration ◽

Sand Body ◽

Shahejie Formation

Guided by the theory of petroleum system, we analyzed hydrocarbon accumulation elements and conditions of the Shahejie Formation in Tangzhuang area and concluded the hydrocarbon accumulation model based on the geological and geophysical data. Hydrocarbon comes from the source rock of Es3 in Linyi sub-sag located to the southeast of Tangzhuang area. Reservoir mainly is clastic, followed by carbonate. There are 4 source-reservoir-cap assemblages in the Shahejie Formation. The Es3 source rock of different tectonic units in Linnan sub-sag has experienced different hydrocarbon generation stages. The central region experienced two hydrocarbon generation stages while the edge only experienced one stage. The hydrocarbon generated by the source rock of Es3 in Linnan sub-sag mainly migrated to Tangzhuang area along fault and sand body. The structural trap is the dominant type followed by structure-lithologic trap and lithologic trap. Based on the analysis of hydrocarbon accumulation condition, we concluded the lower generating and upper reserving model of the study area. The findings will play an important role in guiding Tangzhuang oil and gas exploration.

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Fine Characterization of Sand Body in the Front of the Fluvial Delta: Taking the VII Oil Group of N21 Reservoir in Gasikule Oilfield as an Example

Geofluids ◽

10.1155/2021/6671855 ◽

2021 ◽

Vol 2021 ◽

pp. 1-14

Author(s):

Jun Sheng ◽

Jincheng Liu ◽

Qingshan Qi ◽

Xin Li ◽

Wulin Tan ◽

...

Keyword(s):

Barrier Layer ◽

Development Model ◽

Modeling Technology ◽

Body Development ◽

Sand Body ◽

Sedimentary System ◽

First Time

Taking the VII oil group of N21 reservoir in Gasikule Oilfield as an example, the sedimentary time unit was divided into the barrier layer, interbed, and sand bed by analyzing the sedimentary system and sand body development model in this paper. The single sand body was analyzed for the sand bed time unit. The residual muddy intercalation period division theory was proposed for the first time to divide the sedimentary periods of the sedimentary time unit of the sand bed. Finally, a new “sandwich” layer point coincidence modeling technology was proposed to characterize the sedimentary time units of a barrier layer accurately and interbed and finely describe the sedimentary time unit of the multiperiod sand bed.

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Design, Testing and Field Deployment of an Online Sand Sampling and Particle Size Analysis Package

10.2523/iptc-21855-ms ◽

2021 ◽

Author(s):

Jonathan Ambrose ◽

Alex Mackie ◽

John Yung Lee ◽

Ovidiu Cristian Bibic ◽

M. Shamir A. Rahim ◽

...

Keyword(s):

Particle Size ◽

Closed Loop ◽

Oil And Gas ◽

Production Systems ◽

Particle Size Analysis ◽

Control Surface ◽

Size Analysis ◽

Time Data ◽

Oil And Gas Exploration ◽

Sand Control

Abstract Particle Size Analysis (PSA) of formation or produced sand is an important process in oil and gas exploration and production. This information is required to design downhole sand control, surface sand monitoring and removal systems, and to predict erosion in completion and production systems. A major operator in Malaysia required PSA data as well but found it a challenge as their wells, located offshore in Field Z, contain high amounts of contaminants such as TENORM, Mercury and Hydrogen Sulphide (H2S). Manually collecting produced sand samples was deemed too hazardous to people and the asset thus a closed loop Online Sand Sampling and PSA package was developed and deployed offshore. Samples were taken directly off flowline sample points, flowed through an online PSA system and continued its flow path to a closed loop drain line. The system therefore collected liquid, gas, and sand samples without any need for manual handling thereby eliminating exposure of harmful substances to personnel. A field laptop, running propriety software, connected via ethernet cable to the PSA system continuously measure and record the size of sand particles as they flow through the said system. This allowed the offshore execution team to view and record particle size data in real time. Data collated was available for further analysis onshore because the file format of the PSA software allows play back to refine particle images captured during the sampling operation. This was completed for 32 wells with the majority of the sampling providing good clear particle size information. Results were re-run and analysed again onshore by a sand management technical team from both the operator and service provider. The results were comparable to lab analysed samples of commonly used Laser Particle Size Analysis (LPSA). Therefore this first of its kind method provides a novel way for operaters to sample sand and solids in hazardous and also non hazardous environments.

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Analysis of Sequence Architecture and Hydrocarbon Accumulation Models: An Example from Hailar Basin, Northeastern China

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.962-965.3 ◽

2014 ◽

Vol 962-965 ◽

pp. 3-7

Author(s):

He Liu ◽

Wei Huang ◽

De Feng Zhu ◽

Jun Hui Li

Keyword(s):

Oil And Gas ◽

Steep Slope ◽

Sediment Distribution ◽

Sequence Architecture ◽

Oil And Gas Exploration ◽

Fault Type ◽

Hailar Basin ◽

Distribution Process ◽

Sand Accumulation ◽

Depositional Systems

Wuerxun Sag is one of the main oil and gas exploration and development zones in the Hailar Basin. Comprehensive research on the sequence architecture and depositional filling during the Early Cretaceous shows that filling sequences are controlled by tectonic evolution and have distinct phases. The sequence configuration can be divided into three types: steep-slope type, step-fault type and deep sub-sag type. Tectonism controls the sediment distribution process and sand accumulation. Results show that different tectonic units have characteristic sequence styles and depositional systems. Different sequence patterns also determine different kinds of reservoirs in different tectonic units. The fault-controlled steep-slope area mainly develops fault nosing structure reservoirs and fault lithologic reservoirs; step-fault belts in gentle slope areas develop fault-block reservoirs and fault-lithologic reservoirs; in deep sub-sag areas sand lens reservoirs develop. In addition, the margins of deep sub-sag areas probably develop fault-lithologic reservoirs.

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Sand Free Production Success Through Proven Technology Enabler from An Untapped Heterogeneous Reservoir Zone Utilizing Gravel Pack Replacement Methodology

Proc. Indon. Petrol. Assoc., Digital Technical Conference, 2020 ◽

10.29118/ipa20-e-52 ◽

2020 ◽

Author(s):

Y. Anggoro

Keyword(s):

Oil And Gas ◽

Erosion Resistance ◽

Cost Effective ◽

High Rate ◽

Screen Design ◽

Sand Control ◽

Rules Of Thumb ◽

Production Success ◽

Control Technologies ◽

Gravel Pack

The Belida field is an offshore field located in Block B of Indonesia’s South Natuna Sea. This field was discovered in 1989. Both oil and gas bearing reservoirs are present in the Belida field in the Miocene Arang, Udang and Intra Barat Formations. Within the middle Arang Formation, there are three gas pay zones informally referred to as Beta, Gamma and Delta. These sand zones are thin pay zones which need to be carefully planned and economically exploited. Due to the nature of the reservoir, sand production is a challenge and requires downhole sand control. A key challenge for sand control equipment in this application is erosion resistance without inhibiting productivity as high gas rates and associated high flow velocity is expected from the zones, which is known to have caused sand control failure. To help achieve a cost-effective and easily planned deployment solution to produce hydrocarbons, a rigless deployment is the preferred method to deploy downhole sand control. PSD analysis from the reservoir zone suggested from ‘Industry Rules of Thumb’ a conventional gravel pack deployment as a means of downhole sand control. However, based on review of newer globally proven sand control technologies since adoption of these ‘Industry Rules of Thumb’, a cost-effective solution could be considered and implemented utilizing Ceramic Sand Screen technology. This paper will discuss the successful application at Block B, Natuna Sea using Ceramic Sand Screens as a rigless intervention solution addressing the erosion / hot spotting challenges in these high rate production zones. The erosion resistance of the Ceramic Sand Screen design allows a deployment methodology directly adjacent to the perforated interval to resist against premature loss of sand control. The robust ceramic screen design gave the flexibility required to develop a cost-effective lower completion deployment methodology both from a challenging make up in the well due to a restrictive lubricator length to the tractor conveyancing in the well to land out at the desired set depth covering the producing zone. The paper will overview the success of multi-service and product supply co-operation adopting technology enablers to challenge ‘Industry Rules of Thumb’ replaced by rigless reasoning as a standard well intervention downhole sand control solution where Medco E&P Natuna Ltd. (Medco E&P) faces sand control challenges in their high deviation, sidetracked well stock. The paper draws final attention to the hydrocarbon performance gain resulting due to the ability for choke free production to allow drawing down the well at higher rates than initially expected from this zone.

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