Flownex 8.8.0 turbo-charges the thermal-fluid system engineer’s dream design tool, with yet another release. Saving engineering time, ’cause time is money…
With Global engineering software companies adopting, integrating and co-simulating with Flownex its holistic capabilities have enormously progressed
ANSYS Workbench Integration
An add-in has been developed for ANSYS Workbench that allows Flownex® to be added to Workbench. The Flownex® add-in lets users add Flownex® analysis to Workbench, open Flownex® from Workbench and perform studies with Flownex®. It operates in a way similar to the existing Excel add-in in Workbench. Figure 1 shows the Flownex® add-in in Workbench.
Generic Nuclear Reactor
Flownex has expanded the Nuclear Reactor capability to simulate Molten Salt (liquid fuel) Reactors (MSR), Liquid Metal Cooled Reactors (LMCR) and High-Temperature Gas-cooled Reactors (HTGR) of any geometry.
The new “Generalized fuel zone” in the Flownex® Nuclear Reactor model is capable of handling any fuel geometry and any fluid type. It expands the geometry capability to plate fuel, cylindrical fuel rods, spherical fuel elements, irregular cross section fuel (like the cross-shape produced by Lightbridge), as well as prismatic block fuel used in some HTGRs.
Appropriate pressure drop and heat transfer correlations can be selected from the built-in library or defined by the usr.
For neutronic calculations, the “Generalized fuel zone” can provide temperature feedback, as well as heat generation in all solids and in the core coolant.
Bulk Air Cooler | Component
A Bulk Air Cooler component has been added to simulate heat exchange between process water and an air stream. The heat transfer is mostly driven by mass transfer between the air and water stream and to a limited extent by convective heat transfer. In the case of bulk air coolers, the primary objective is the cooling of air using the evaporative cooling of the process water. The modelling of these bulk air coolers fundamentally relies on Flownex®’s capability to model mixtures of air-water-vapour fluids using the two-phase and non-condensable mixture model. By specifying a single input called the “Factor of merit”, the complete operating envelope of the bulk air cooler can be modelled.
Cooling Tower | Component
A Cooling Tower component has been added to simulate heat exchange between process water and an air stream. With cooling towers, however, the primary objective is the cooling of process water using evaporative cooling to the air stream. The modelling of these cooling towers fundamentally relies on Flownex®’s capability to model mixtures of air-water-vapour fluids using the two-phase and non-condensable mixture model.
Two methods are implemented in Flownex® for the modelling cooling towers. The Factor of merit model uses a single parameter to characterise the operating envelope thereof. An alternative approach of somewhat higher fidelity is based on the Merkel model approach, and divides the cooling tower in three distinctive zones, namely:
- Spray zone – water distribution into the cooling tower, normally using spray nozzles.
- Fill zone – water is distributed onto or between a fill media to increase the surface contact area between the water and air.
- Rain zone – water from the fill zone “rains” into the collection pond to allow further contact between water and air.
Both forced draught, as well as natural draft cooling towers, can be modelled in Flownex®.
Pipe Elevation Profile
An elevation profile for pipes has been added. This allows the easy simulation of complex pipelines with a single discretized pipe. Figure 5 shows the Pipe Profile Editor window that can be used to specify the elevation profile for pipes.
The Electrical Library has been updated to improve its usability and broaden its application. Basic components such as the Resistor, Capacitor and Inductor were added to serve as building blocks for large load systems. Three phase inputs and results will prove to be more valuable to the user. Characteristics (such as more impedances forming the equivalent circuits) are added to the Induction Motor and the Transformer for an improved component specification. The added Motor component allows the user to specify a motor characterised by a torque-speed curve. The Motor and Induction Motor component can execute with a mechanical-flow network using a connection to the Flownex® Shaft.
Links to other Software
- The Fluent – Flow solver coupling has been updated to make it easier to use. Both the server and journal file versions were updated.
- Simulink, Matlab and Labview links have been updated to work with API and not with Memory Map anymore. The Memory Map functionality has been removed due to 64bit compatibility issues.
- A Help File has been added for the Python Link.
- The ability to run multiple Flownex® instances via the API has been added. This is a setting that can be turned on and off in the application settings.
- Flownex® is now available in 64bit.
- Added a Property Monitor window that can be used to pause the simulation during transients when properties attain certain values. It can also highlight properties when they have changed.
- Improved complex values parsing. Users do not have to put spaces in between the complex and imaginary parts anymore.
- Added the ability to transfer data using Data Transfer Links before and after each flow solver iteration in transient/dynamic simulations as this was only possible for steady state simulations.
- Use FIPS compliant cryptographic provider so Flownex® can run on FIPS compliant computer setups.
- Added the capability to preserve an active page when automatically re-opening all pages.
- Added the ability to prevent Flownex® from opening newer databases.
- Added a button to the License Setup window so that license information can be copied to the clipboard.
- Added the capability to allow multiple instances to run through the API. A setting was added that turn this option on and off.
Fluids, Charts & Lookup Tables
- Made data references that use others (like mixtures) copy or move their dependencies with them – the user is asked for confirmation.
Improved the Error reporting when a Chart or Fluid was not found to identify the item that was using that Chart or Fluid.
Made the Positive Displacement Pump chart show all of the lines on its charts at the same time as only the selected line was shown.
Made the Variable Speed Pump show all the lines on its charts at the same time as only the selected line was shown.
Issue a meaningful error when a Material Property Table only contains no valid data.
Save units selected for Constant Properties in Fluid and Material dialogs.
- Made pipe diameters and areas dynamic so that it can be changed within sequential iterations and during transients.
- Added Fixed Exit Temperature option to the Flow Resistance element.
- Added Pump head result to Variable Speed Pump.
- Diameter and Wall thickness have been added as a result for all relevant components.
- Prevent Fix on sovler value options from being used in Steady State
- Updated the Pressure Relief and Pressure Regulating Valve icons, as seen in Figure 14.
- Improved film compounding in Film Convection component to use appropriate upsteam cooling slot conditions.
Added an example that shows how to issue warnings and errors from a Script.
Simplified the way that scripts convert to and from Repository Scripts – the “Yes/No” option on the input grid was removed to make it less confusing.
Made operator overloading for C# consistent between doubles and integers so that doubles and integers can be used in the same way in the Quick Scripts.
Made Variables setup grid disabled when Script is a Repository Script in Quick Script.
Added a flag to Iterative Script to indicate it is the last iteration.
- Added the reactivity unit “mN” as well as Dollar reactivity values.
- Changed Heat Transfer options to Neutronics options on Reactor dialog.
- Added Flow and Solid volumes in ARR file.
- Added Average moderator temperature to increment results and to ARR file.
- Added Fission power as a result on Reactor.
- Duplicate power specifications were taken off the Reactor Chart Zone and the transient and steady state Reactor inputs were simplified.
- Preserve column and row geometry in Nuclear Reactor settings when inserting rows and columns in the Nuclear Reactor Geometry editor.
- Added options to add rows and columns above and below and before and after on Nuclear Reactor Geometry editor.
- Added Moderator, Fuel and Xenon reactivity results. Changed External reactivity name to Control rod reactivity, as seen in Figure 15.