Portable PIPEPHASE 91 1
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Portable PIPEPHASE 91 1: A Powerful Tool for Pipeline Simulation and Optimization
Portable PIPEPHASE 91 1 is a software application that allows users to perform steady-state and transient simulations of multiphase flow in pipelines and networks. It can handle complex geometries, fluid properties, equipment models, and operational scenarios. Portable PIPEPHASE 91 1 can also optimize pipeline design and operation by finding the optimal diameter, pressure, flow rate, pump configuration, and valve settings.
Portable PIPEPHASE 91 1 is based on the PIPEPHASE software developed by Schlumberger, a leading provider of technology solutions for the oil and gas industry. PIPEPHASE has been used for over 30 years by engineers and operators worldwide to design, analyze, and optimize pipelines and networks. Portable PIPEPHASE 91 1 is a portable version of PIPEPHASE that can run on any Windows-based computer without installation or licensing requirements. Users can easily transfer their projects and data between different machines using a USB flash drive or cloud storage.
Portable PIPEPHASE 91 1 offers several advantages over other pipeline simulation software. It has a user-friendly graphical interface that allows users to create and modify pipelines and networks using drag-and-drop features. It has a comprehensive database of fluid properties and correlations that can handle various types of fluids, such as oil, gas, water, condensate, and multiphase mixtures. It has a robust solver that can handle nonlinear equations, pressure drops, heat transfer, phase changes, compressibility, and slippage effects. It has a flexible output system that allows users to generate tables, charts, maps, reports, and animations of the simulation results.
Portable PIPEPHASE 91 1 can be used for various applications in the oil and gas industry. It can be used to design new pipelines and networks or to evaluate existing ones. It can be used to simulate normal operation or to test different scenarios, such as start-up, shut-down, ramp-up, ramp-down, pigging, flushing, leak detection, and emergency response. It can be used to optimize pipeline performance by finding the optimal operating conditions or by identifying potential bottlenecks, constraints, or inefficiencies. It can also be used to integrate pipeline simulation with other software tools, such as reservoir simulators, process simulators, economic models, or optimization algorithms.
Portable PIPEPHASE 91 1 is a powerful tool for pipeline simulation and optimization that can help users to improve their pipeline design and operation. It is easy to use, reliable, accurate, and portable. Users can download Portable PIPEPHASE 91 1 from this link or contact Schlumberger for more information.
In this section, we will provide a brief overview of how to use Portable PIPEPHASE 91 1 for pipeline simulation and optimization. The following steps are required to perform a simulation:
Create a new project or open an existing one. A project consists of a set of files that store the pipeline and network data, the fluid properties, the simulation settings, and the output results.
Define the pipeline and network geometry. Users can create and modify pipelines and networks using the graphical interface or by importing data from external sources, such as Excel files, GIS files, or other software tools. Users can also add equipment models, such as pumps, valves, compressors, heaters, coolers, separators, meters, and controllers.
Define the fluid properties and correlations. Users can select from a comprehensive database of fluid properties and correlations that can handle various types of fluids, such as oil, gas, water, condensate, and multiphase mixtures. Users can also customize or create their own fluid properties and correlations using the built-in editor or by importing data from external sources, such as PVT files or laboratory reports.
Define the simulation settings and scenarios. Users can specify the simulation mode (steady-state or transient), the time step size, the convergence criteria, the output frequency, and the output variables. Users can also define different scenarios by changing the boundary conditions, such as pressure, flow rate, temperature, or composition at the inlet or outlet nodes of the pipelines and networks.
Run the simulation and view the output results. Users can run the simulation by clicking on the Run button or by using the Batch mode to run multiple scenarios in sequence. Users can view the output results using the graphical interface or by exporting them to external sources, such as Excel files, PDF files, or HTML files. Users can also generate tables, charts, maps, reports, and animations of the simulation results.
To perform an optimization, users need to define an objective function and a set of constraints. The objective function is a mathematical expression that represents the goal of the optimization, such as minimizing cost, maximizing profit, maximizing throughput, minimizing energy consumption, or minimizing emissions. The constraints are a set of equations or inequalities that represent the limitations or requirements of the optimization problem, such as minimum or maximum values for pressure, flow rate, diameter, pump configuration, valve settings, or equipment specifications.
Users can define the objective function and constraints using the graphical interface or by importing them from external sources. Users can also select from a list of predefined objective functions and constraints that are commonly used in pipeline optimization problems. Users can then run the optimization by clicking on the Optimize button or by using the Batch mode to run multiple optimizations in sequence. Users can view the optimization results using the graphical interface or by exporting them to external sources. Users can also compare different optimization results using tables, charts, maps, reports, and animations. aa16f39245