Download - Safety Brochure Digital(s)
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SAFETY
APPLICATION OF FLOWNEX IN THE SAFETY INDUSTRY
Safety plays a fundamental role in the engineering society. The use of Flownex can ensure that systems are designed safe and
reliable, and can also aid in accident prevention.
Flownex enables users to design and optimize a system, while ensuring that the highest quality and standards are met.
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2BRINGING NUCLEARQUALITY AND
STANDARDS TOSYSTEM SIMULATION
Flownex is developed in an ISO 9001:2008 and NQA1 quality assurance system environment. Flownex is the only software of its kind to hold a nuclear accreditation, a testament to the quality, reliability and accuracy of our simulation software.
Flownex Simulation Environment delivers technology that enables the user to analyze how systems concerned with fluid motion and heat transfer will behave in the real world.
Flownex system simulation relays the overall effect of changing specific component properties, allowing clients to extensively examine all possible variations in the design and optimization of systems.
On a global scale leading organizations apply our software and service offerings to achieve maximum potential of their systems both in design and operational states. Our promise of fast, reliable and accurate system and subsystem level simulation has immensely benefited our clients. The use of Flownex has set our clients apart from their competitors allowing them to pursue frontiers of engineering simulation. The global demand for Flownex has shown exponential growth over the last few years, and as more organizations adopt our technology we are continuously striving to push the boundaries in system simulation.
GROWINGDEMAND
FOR SYSTEMSIMULATION
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3Flownex model used to detect whether cavitation occurs at the first stage of a multi-stage pump.
Flownex has the capability to detect whether cavitation can occur. Knowing whether there is a possibility of cavitation helps to minimize the risk of equipment damage.
CAVITATION DETECTION
GAS CONCENTRATIONS & PRESSURE PULSES
Bleed flow
FLOWNEX APPLICATION IN THE SAFETY INDUSTRY
Flownex can be used to model pressure pulses and to track gas concentrations, for example, when modelling mine blasting fumes. The gas concentration can be modelled by either using trace elements convective transport or specifying a gas mixture in Flownex and then observing the dilution and propagation through the network.
Flownex assisted in solving a com- plex and potentially dangerous problem during commissioning of the unit. It ensured that this specific problem did not cause any delays in the commissioning process.
Nicolaas Hallatt (Pr.Eng.)Turbine Plant Engineer
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4FORCE ANALYSIS
Flownex calculates the forces due to the pressure difference and velocity changes on the pipe and bend components in a network.
t
Bend angle
Forces perpendicular to inlet Magnitude of resultant force
Forces parallel to inlet
OUTLET
INLET
WATER HAMMER ANALYSIS
- Prediction of the maximum pressure in the pipeline. - Create a safe design and save on costs. - Ability to perform sensitivity analysis. - Ability to model different scenarios.
Water hammer effects can easily be investigated in simple and complex networks, while taking the fluid and pipe wall elasticity into account.
Flownex provided a convenient way of obtaining all the fluid forces on the pipe system, as required for the pipe stress analysis. The flexibility of the modelling approach in Flownex made it possible to include all the remote systems that influence the local pressure waves, but only at the level of detail that was necessary. This valve closure and pressure wave simulation definitely saved money and time by preventing an overly conservative high-pressure pipe design.
Herman van Antwerpen Simulation Design Engineer
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5BOILER HEADER-CRACKING
TURBINE PROTECTIONTWO PHASE CAPABILITIES
The root cause analysis of dynamically hazardous movements in the distillate lines to a plant deaerator was investigated with Flownex. Flownexs simulation optimization tool was used to determine the preferred two-phase flow regime. By using Flownex to identify the cause, it was possible to maintain the planned commissioning schedule and improve the existing plant design, thereby also removing the safety risk of unwanted dynamic line movements.
Flownex has the capability to simulate, design and analyze two-phase flow.
Flownex can be used to determine the type of two-phase flow regime.
Steaming turbines
Connecting Tube
Flue gas
Downcomers
Water
PlatenEvaporator
REAL-WORLD APPLICATIONS:
Two phase flow regimes
Simulation 1: Existing Plant Set-up
Simulation 2:With flow area of distributor increased
HEAT TRANSFER
Operation of the pressure regulators during the start-up of the turbines at a gas-fired power station was studied and simulated in Flownex. The major advantage of using Flownex is that the capacitance of the pipe material and the full Joule-Thompson effect could be simulated. The model was also able to determine if the proposed trace heating and insulation system would be sufficient.
The Flownex model used for analysis
REGULATOR TEMPERATURE ANALYSIS
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6SYSTEM DESIGN
CONTROL
Flownex can be used to do parametric studies to determine the effect of varying different parameters in a system through a sensitivity analysis or optimize the system by using the optimizer feature in Flownex.
Through a sensitivity analysis, the relationship between the excess power of the shaft, compared to the heat removed from the system by the pre-cooler for different water inlet temperatures, can be determined.
An air cycle chiller was simulated to show the ability of the controller in Flownex to control the heat exchanger thermal inertia and turbo machine rotational inertia during a transient simulation.
Two shaft power conversion unit (PCU) for a pebble bed type High Temperature Gas-Cooled Reactor (HTGR).
Schematic representation of standard air cycle chiller.
COMP. TURB
P
S
P
S
P S
COMP. BoosterCompressorHigh PressureCompressor
Coolingchamber
Anyone familiar with transient heat transfer of flow systems with complicated geometries will tell you that such an analysis would be beyond the capability of most engineering houses. Flownex enabled me to obtain reliable ball-park results in a matter of a few hours. When the potential cost of equip-ment failure is tens of millions of dollars, this is an amazing result which highlights the in-credible power and flexibility of Flownex.
Hannes van der WaltSenior Thermal & Process Engineer
RecuperatorPre-cooler
GENERATOR
HPC
LPC
HPT
LPT
P
S
PS
P
S
IntercoolerHigh temperaturegas-cooled reactor
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7Flownex Simulation Environment enables engineers to predict, design and optimise for flow rates, pressures, temperature and heat transfer rates in fluid systems. Such systems include anything from ventilation systems and water and gas distribution systems up to boiler designs and complete power generation cycles.
The ability to simulate systems with any combination of liquid, gas, two-phase, slurry and mixture flows in both steady state and dynamic cases makes Flownex the most powerful simulation tool of its kind.
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We employ masters and doctorate level qualified engineers to develop and support Flownex, guiding you on how to use our software tools more effectively and maximize your return on investment.
Initial development.
Development of the Implicit Pressure Correction Method (IPCM) algorithm.
Aircraft engine combustion systems for Rolls-Royce.
Transient/Dynamic simulations.
HTGR simulation.
Gas mixtures & conduction.
Object oriented.
Rotating components.
Two phase.
Combustion.
Equation element, API.
Control & electric, MS Excel.
Simulation Environment, in-condensables.
Slurry, expanded combustion.
Expanded two-phase, expanded heat transfer, trace elements, RELAP coupling.
Gas turbine secondary flow modelling, steam turbine modelling, GIS importing and coordinate system drawing, supersonic flow, simplified scripting, visualization & graphing, 3D drawing & importing.
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PHY
SICS / C
OM
PON
ENTS
COREMODULES
LIBRARYMODULES
INTEGRATIONMODULES
Basi
c th
erm
alu
id m
odul
e
Adv
ance
d u
id
ther
mal
mod
ule
Des
ign
and
anal
ysis
mod
ule
Tran
sien
t m
odul
e
Nuc
lear
m
odul
e
Con
trol
m
odul
e
Elec
tric
al
mod
ule
Exte
ndab
ility
m
odul
e
EES
mod
ule
OPC
mod
ule
Rela
p M
odul
e
Mat
hCad
m
odul
e
API
mod
ule
Basic Flownex component library
Basic heat transfer
Advanced heat transfer
Turbo secondary ow
Combustion
Reactors
Control library
Electrical library
Compound components
INTEG
RATION
&A
UTO
MATIO
NAlarms
Scripting
Excel component
Relap coupling
EES coupling
Mathcad coupling
API
OPC
TOO
LS
Designer
Optimizer
Sensitivity analysis
Visualization
Result tools
Flow solver
Transient solver
Extendability
FLUID
MO
DELS
Liquid
Gas
Gas mixtures
Incondensable
Slurry
Two-phase
Trace elements
SOLV
ER