Next-Generation Release Device: Strong, Safer, Efficient, and Rigorously Qualified

Au, Greg; Sheiretov, Todor; Elstrop, Stephanie; Rivas, Caroline Stephan; Bellicard, Claire; Couble, Yoann

doi:10.2118/189929-ms

Cited by 3 publications

(1 citation statement)

References 8 publications

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“…It is found that, among the downhole robots, only telescopic downhole robots can meet the drilling requirements. 7 However, the telescopic type of downhole robot is still in the development stage. The high temperature and high pressure resistance of the sealing structure is one of the main reasons restricting the application of telescopic type of downhole robot.…”

Section: Introductionmentioning

confidence: 99%

Study on dynamic sealing performance of combined sealing structure of telescopic type of downhole robot by using HTHP coupling method

et al. 2021

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The sealing performance will directly affect the operation of downhole robot under HTHP condition. Traditional analysis methods of sealing performance are that the temperature and pressure is loaded respectively. This can not really evaluate the sealing performance. Besides, the simulation process is: Step 1: pre-compress O-ring to produce contact force. According to the contact pressure, select the compression ratio to calculate the displacement of the slip ring. Step 2: load fluid pressure on the O-ring. This simulation method is to directly load pressure on the undeformed O-ring. However, the O-ring will deform after pre-compression. Therefore, this simulation method is not accurate. In order to make the simulation data more accurate, calculate the data of shape, stress, and strain of O-ring caused by pre-compression caused by assembly. Then, import the deformation body containing the real data of shape, stress, and strain into a new model. On the basis, establish the numerical simulation model of piston, piston guide rod, O-ring, and FTS-ring with HTHP loads is. Finally, calculate and analyze. When the compression ratio of the O-ring is about 14%, the sealing performance is good. What’s more, the distribution of contact stress and Von Mises of the O-ring at 8.3 mm/s of motion speed are analyzed. The results show that the foot shaped combined sealing structure can keep a good dynamic sealing performance under HTHP condition. This paper provides a theoretical basis for the analysis of the dynamic sealing performance by using HTHP coupling method. In the analysis of sealing performance: the hydraulic pressure is loaded to the real model with the real shape, stress, and strain produced by the O-ring assembly. This can more accurately evaluate the sealing performance under HTHP condition. It also provides a reference for the dynamic sealing structure design of downhole tools.

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Section: Introductionmentioning

confidence: 99%

Study on dynamic sealing performance of combined sealing structure of telescopic type of downhole robot by using HTHP coupling method

et al. 2021

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Nonlinear Dynamic Model and Characterization of Coiled Tubing Drilling System Based on Drilling Robot

Jian

Liu

Zhu

et al. 2020

J. Vib. Eng. Technol.

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A Novel Approach to Wireline Debris Removal

Gourmelon

Wiesenborn

Chochua

2019

Day 1 Tue, March 26, 2019

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A new type of wireline-powered debris removal system that efficiently captures and retains a wide variety of wellbore debris types is presented. The system's unique benefits and performance are demonstrated through modeling and testing in controlled conditions. Wireline-powered debris removal technology uses localized fluid circulation generated downhole to vacuum debris into bailers for capture. Challenges with conventional systems are related to the ability to continuously mobilize and separate a variety of debris including fine particulates and cohesive debris-binder mixtures. The new wireline debris removal system improves on previous technology by addressing the specific challenges of each of the debris types. This performance improvement is enabled by using a progressing cavity pump (PCP) to create powerful bidirectional suction pressure and a staged bailer configuration with parallel flow filters for maximum fill efficiency. Pump performance is compared analytically for a centrifugal pump and a PCP to demonstrate the benefits of the PCP for debris collection applications. These benefits include reverse pumping ability for unsticking the toolstring when operating in debris-filled wellbores. This pump analysis defines a suction pressure budget, which is used to analyze the performance and capabilities of the staged bailer system. The pressure losses and debris accumulation profile of the new top-fed parallel flow filter bailers is determined by using fluid dynamics models. Results of an extensive testing campaign are presented to validate model results. Actual collection performance is presented for a wide variety of debris types using the new debris removal system. The new wireline debris removal system's use of a PCP to generate the necessary vacuum and provide bidirectional capabilities for operational flexibility in combination with maximum debris recovery provided by staged bailers with parallel flow filters will bring new efficiencies and reliability to intervention operations.

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Next-Generation Release Device: Strong, Safer, Efficient, and Rigorously Qualified

Cited by 3 publications

References 8 publications

Study on dynamic sealing performance of combined sealing structure of telescopic type of downhole robot by using HTHP coupling method

Study on dynamic sealing performance of combined sealing structure of telescopic type of downhole robot by using HTHP coupling method

Nonlinear Dynamic Model and Characterization of Coiled Tubing Drilling System Based on Drilling Robot

A Novel Approach to Wireline Debris Removal

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