Modelling of High Point Vents in water gathering systems – a new approach using Simcenter Flomaster
Jurgen Sprengel A * , Pedro Milano B , Ryan Sfand B and Doug Kolak CA JS Pump and Fluid System Consultants, 26 Glendale Grove, Moorooka, Qld 4015, Australia.
B Arrow Energy Pty Ltd, 39/111 Eagle Street, Brisbane, Qld 4000, Australia.
C Siemens Digital Industrial, Plano, TX 75024, USA.
The APPEA Journal 62(1) 106-115 https://doi.org/10.1071/AJ21135
Submitted: 31 December 2021 Accepted: 14 February 2022 Published: 13 May 2022
© 2022 The Author(s) (or their employer(s)). Published by CSIRO Publishing on behalf of APPEA.
Abstract
The cost-efficient extraction of coal seam gas (CSG) is the ultimate objective of every CSG project. One challenge is that gas holdups in water gathering lines can significantly obstruct water removal by causing higher back pressure on the wells, thus resulting in lower dewatering rates with subsequent delays in expected gas production. Gas holdups originate from entrained gas entering the wellhead pumps and from dissolved gas bubbling off in water gathering pipelines. Gas holdups are mechanically removed by High Point Vents (HPVs) installed at pipeline high points, with the efficiency of gas removal directly impacting project economics. A new hydraulic modelling approach enables the realistic simulation of two-phase flow regimes in a single-phase solver by utilising hydraulic components designed to separate gas and water. This modelling process offers major advantages over the traditional gas water ratio approach, as it enables the addition of individual HPVs to be analysed for their impact on the pressure reduction in water gathering pipelines. Modelling can be performed for any network complexity in either steady-state or transient simulation, enabling the analysis of the entire water gathering network over its life span of several decades. An operating envelope of well and pipeline pressure can be generated for an idealistic gas-free network, showing the lowest pressure and a network with fully developed gas holdups and resulting in the maximum possible back pressure. The paper includes a benchmarking study of an existing complex water gathering system confirming the practicality and accuracy of this game changing modelling approach.
Keywords: coal seam gas, CSG well back pressure reduction, flow assurance, gas holdup, gas removal, HDPE pipe, high point vents (HPVs), HPV efficiency, pressure benchmark, Simcenter Flomaster, water gathering network, water system modelling.
Jurgen Sprengel, Principal, JS Pump and Fluid System Consultants. JS Pump and Fluid System Consultants, specialists in hydraulic design and modelling of complex fluid networks and advanced control systems, are providing flow assurance services for a range of industries. With more than 25 years of experience with the Simcenter Flomaster software, JS Pump and Fluid System Consultants are now focusing on coal seam gas (CSG) water gathering systems, particularly the hydraulic modelling and optimisation of high point vent operation. |
Pedro Milano, Lead Process Engineer, Arrow Energy Pty Ltd. Pedro Milano is a Lead Process Engineer with more than 20 years of experience in the design, optimisation and operation of oil and gas production systems, including pipeline systems. During the last 9 years, he has been working in different projects related to process systems associated with the CSG industry, among them the flow assurance and design of gas and water gathering networks. |
Ryan Sfand, Senior Process Engineer, Arrow Energy Pty Ltd. Ryan Sfand is a Senior Process Engineer with more than 14 years of experience in the oil and gas industry and 7 years in the unconventional gas industry. Most of Ryan’s work in the unconventional gas space has focused on lease facilities and gathering network design. |
Doug Kolak, Business Development Manager, Siemens Digital Industries. Doug Kolak is the Business Development Manager for the Energy Industries inside of the System Simulation group at Siemens Digital Industry Software. He has over 15 years of experience in thermal and hydraulic simulation with a focus on the challenges faced by oil and gas and process industries. |
References
Chen J, Zhao J, Qian K, Welch B, Taylor M (1992) Bubble Rise Velocity in an Inclined Channel and The Effect of Channel Width. In ‘11th Australasian Fluid Mechanics Conference, Hobart, 14–18 December 1992’. (University of Tasmania: Hobart)Miller DS (2020) ‘Internal Flow Systems.’ 3rd edn. (Mentor Graphics: Ireland)