Use FlowMaster to quickly perform hydraulic calculations for dozens of element types. Logitech Gaming Software EOSInfo ROBLOX Studio.
Companies can maximize their return on investment by integrating FloMASTER at every stage of the development process, taking advantage of the data management and collaborative capabilities of this analytical tool. It is used by companies across a wide range of industries to reduce the development time and costs of their thermo-fluid systems. It helps systems engineers to:. Simulate pressure surge, temperature and fluid flow rates system-wide. Understand how design alterations, component size, selection and operating conditions will affect the overall fluid system performance accurately and quickly. “When modelling multi arm junctions such as automotive thermostats and pump housings, characterizing individual flow paths as parallel and independent losses can give rise to 15 to 20% error in predicting mass flow rates through an outlet.
This error is eradicated by considering the effect of changes in branch pressure drops with changing flow rates in the other branches. Using FloEFD to perform full spectrum 3D CFD characterization of the housing and integrating inter-dependent flow channel interactions into a FloMASTER N-Arm component improves simulation accuracy, confidence and trust reducing physical testing times and ultimate time to market. ” Sudhi Uppuluri, Principal Investigator, Computational Sciences Experts Group. Open, Extendable Architecture.
Create bespoke component models. Create scripts for controlling components or networks. Open API structure allows integration into user product development process including in-house codes, CAE, manufacturing and optimization tools.
Functional Mock-up Interface (FMI) Model Export support allows FloMASTER models to be shared across other CAE tools during the design process through an independent standard for model exchange. Export the hydrodynamic forces generated by a transient event as a time history to leading pipe stress analysis tools such as SST CAEPIPE and Integraph® CAESAR II®. Design Optimization Capability The ‘Experiments’ feature in FloMASTER provides users with the ability to conduct superior ‘what-if’ analyses for 1D thermo-fluid analysis. Using a Latin Square algorithm, FloMASTER helps users generate unique combinations of distributed input values between specific bounds. This ability creates an ideal foundation for the creation of meta-models and response surfaces that characterize a FloMASTER system response. Monte Carlo simulations can be performed to produce simulation results based on a probability distribution generated from a mean and standard deviation for selected input parameters.
This allows the effect of small variations in input values to be examined and enables FloMASTER to be used in risk analysis and quality control environments such as Design for Six Sigma (DFSS).
Private company Industry Engineering Simulation Software Founded 1992 Headquarters United Kingdom Products Flowmaster ® (now sold as FloMASTER) Mentor Graphics Corporation Website www.mentor.com/FloMASTER Flowmaster Ltd. Was a leading British Engineering Simulation Software company based in Towcester, UK. Its flagship 1D product, also named ‘Flowmaster’, was first released commercially in 1987 although initial versions went back to the early 1980s having originated from BHRA, the not-for-profit British Hydromechanics Research Association, later to become the BHR Group. Flowmaster 1D thermo-fluid systems simulation software employed a matrix type solver and was the first tool of its type onto the market. It was initially sold and marketed by Amazon Computers Ltd based in Milton Keynes, UK. The software covered many different industries such as, marine, &, process, and.
Flowmaster software itself was based on extensive experimental validation data from ’s internationally respected scientific textbook, ‘’, first published in 1978. A company called Flowmaster International (that later became Flowmaster Ltd) was created in 1992 when Richard Tickle was appointed CEO. During the next ten years Flowmaster experienced significant growth opening international sales offices near Frankfurt, Germany and Chicago, USA. Richard was followed as CEO by Alan Berry who led the company up to its acquisition in 2012 by Mentor Graphics Corporation where it became part of Mentor’s Mechanical Analysis Division.
The Flowmaster product has subsequently been renamed as FloMASTER by Mentor Graphics in 2016 for its V8 release. Evolution of User Interfaces for Flowmaster/FloMASTER: V0, V1, V3, V5, V7 & V8 (1984-2017) Development work first commenced on a commercial computer code that would become ‘Flowmaster’ in the period between 1980 and 1984 based on the extensive BHRA research data from ’s ‘Internal Flow Systems’ for pipework and ducting. Flowmaster V1.0 was subsequently released commercially in 1987. It was the first general purpose 1D CFD flow solver, having ‘pick and drop’ components and an interactive user interface with “joystick” control; all innovations for their time. Its first customer was. By 2002, the 1,000th commercial license of Flowmaster was purchased. Flowmaster V1 was released in 1987.
Flowmaster V2 was released in 1990. Flowmaster V3 was released in 1993.
Flowmaster V4 was released in 1995. Flowmaster V5 was released in 1997. Flowmaster V6 was released in 1999. Flowmaster V7 was released in 2007. FloMASTER (Flowmaster) V8 was released in 2016. Flowmaster helped to pioneer software for virtual hybrid electric vehicles with its integration into the USA-based NREL ‘ADVISOR’ program that sought to simulate a complete vehicle cooling system in 2000.
This idea has evolved into the concept of “” which today is a major driving force in many industries. Flowmaster in 1987 Flowmaster has been added to over the years including the application of the Method of Characteristics to compressible pipe flow systems, a new approach to the modeling of AC components, the first commercial co-simulation link between 1D and 3D CFD software and control models were added in 1999. Industry specific variants of Flowmaster for Automotive, Aerospace, Power and Energy and Gas Turbines and were released from 2007 – 2016. After Flowmaster Ltd was acquired by Mentor Graphics Corporation in 2012 the software has been enhanced numerically and upgraded such that FloMASTER V8 was launched in December 2016 with Organic Rankine Cycle enhancements for Waste Heat Recovery predictions, a new user interface ‘Launchpad’ experience, plus a new integrated 1D-3D CFD workflow that allows for accelerated Simulation Based Characterization (SBC) of multi-arm 3D components inside the 1D systems simulation environment. Version of Flowmaster™ from the early 1980s Product Flowmaster is a general purpose 1D (CFD) code for modeling and analysis of in complex piping and ducting systems of any scale. It is a thermo-fluid systems engineering package that has the ability to simulate flows of gases and liquids, and, moving bodies, and (FSI) through. It uses a solver that allows it to handle accurately fluid transients in complex systems and systems-of-systems such as pressure surge and ‘’.
Flowmaster Software Tutorial
It also has an advanced gas turbine secondary air modeling capability. Typical FloMASTER 1D thermo-fluid automotive engine fuel injection system Technology FloMASTER simulates 1D thermo-fluid systems and complex systems-of-systems through: Empirical Data: The code is underpinned by ’s ' component and fluids data plus Wylie and Streeter’s 'Fluid Transients in Systems' that both allow for simulations to be initiated before detailed design information exists.
The 1D model can then evolve according to the user’s requirements. Solver: Steady state analysis for pressure drop, flow and heat balance calculations to the same model can then be used for dynamic simulations such as pressure surge and water hammer behavior.
CivilStorm
The solver has embedded ‘parametrics’ for design iterations, and a SQL to store and track all models, results, and performance data. Integration: Open APIs allow for the direct integration with product development tools and systems, including optimization codes, and other CAE codes. Software Development Kit (SDK): A suite of tools that enable FloMASTER to be integrated with product development tools and systems, including optimization tools such as Optimus, Control Modeling tools such as Simulink and other CAE tools. Integration is facilitated through an open API which supports COM and.NET as well as through an embedded script editor which allows creation of native macros, scripts and plug-ins. 1D-3D CFD: (MBD) and Simulation-Based Characterization (SBC) features that allow for modeling of components for which data is either difficult to obtain, or non-existent in a 1D sense, to be created. Examples include multi-arm junctions and non-standard ducts and bends. The SBC approach leads to a virtual ‘flow ’ inside the Mentor Graphics FloEFD 3D CFD tool to extend the FloMASTER component catalog.
Flowmaster Software Pricing
^ Miller, D. Internal Flow Systems (3rd ed.). Mentor Graphics Corp. Lewis, R., & Burke, J., “Detailed VTMS Modeling in ADVISOR through Integration with FLOWMASTER2”, ADVISOR User Conference Proceedings, August 2000, Costa Mesa, USA, p162-168. Bancroft, T.G., Sapsford, S.M.
And Butler D.J., “Underhood Airflow Prediction Using VECTIS Coupled to a 1D System Model”, Proceedings of 5th Ricardo Software International Users Conference, Shoreham-by-Sea, UK 2000. Streater, S., “Meeting The Challenge of Organic Rankine Cycle Based Waste Heat Recovery Simulation”, NAFEMS UK Conference, Telford, UK, June 2016. ^ Bornoff, R., “Simulation Based Characterization. A 3D to 1D System Level Thermo-Fluid CFD Workflow”, Mentor Graphics White Paper, 2017.
Tondello, G., Boruszewski, W., Mengele, F., Assato, M., Shimizu S. & Ziegler, S., “Coupled Simulation of the Secondary Air Flow, Heat Transfer, and Structural Deflection of a Gas Turbine Engine”, ASME Turbo Expo Turbine Technical Conference and Exposition, Copenhagen, Denmark, June 11–15, 2012, pp. B., & Streeter, V. L., “Fluid Transients in Systems”, 2nd Edition, McGraw-Hill, 1985,.