1 jrc – ie pisa on 8.9.2004 cfd modelling of accidental hydrogen release from pipelines. h....
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1 JRC – IE Pisa on 8.9.2004
CFD modelling of accidental hydrogen release from pipelines.
H. Wilkening - D. Baraldi
Int. Conf. on Hydrogen Safety
Pisa Sept. 8-10, 2005
1. Motivation2. 2-D Simulations for methane and hydrogen3. 3-D Simulation for methane and hydrogen4. Conclusion
2 JRC – IE Pisa on 8.9.2004
Pipeline disaster in Belgium in 2004
Left picture is a view of the industrial area destroyed by the explosion and the subsequent fire. The right picture shows the fire caused by the natural gas released from the pipeline after being ignited by the explosion.
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Modelling of light methane dispersion (1/2)
Streamlines of high-pressure release from the pipeline and wind at 10 m/s from left to right.
Molar methane concentrations the same case
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Modelling of methane gas dispersion (2/2)
Molar methane concentrations, no wind.
Molar methane concentrations, 10 m/s wind from left to right.
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Comparison to hydrogen
Molar hydrogen concentrations, 10 m/s wind from left to right.
Molar hydrogen concentrations, no wind.
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Comparison of thermal energy released between methane and hydrogen
0
10
20
30
40
50
60
70
0 2 4 6 8 10 12
Time [s]
Th
erm
al E
ner
gy
[GJ/
m]
CH4 10 m/s wind
CH4 no wind
H2 10 m/s wind
H2 no wind
The thermal energy released is very similar for methane and hydrogen until the first gas is leaving the computational domain, the wind keeps the gas within the computational domain longer.
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Methane molar concentrations for wind (top) and no-wind (bottom) case both 7.5 s after the high-pressure release starts. Shown are only those concentrations within the flammability limit. These are the values between 5.3 % and 15 % all other concentrations are set to 0 %.
Flammability limits in methane gas dispersion
8 JRC – IE Pisa on 8.9.2004
Flammability limits in hydrogen gas dispersion
Hydrogen molar concentrations for wind (top) and no-wind (bottom) case. Shown are only those concentrations within the flammability limit. These are the values between 4 % and 74 % all other concentrations are set to 0 %.
9 JRC – IE Pisa on 8.9.2004
Comparison of thermal energy released within the flammability limits
0
2
4
6
8
10
12
14
16
18
20
0 2 4 6 8 10 12
Time [s]
Rel
ease
d T
her
mal
En
erg
y [G
J/m
]
CH4 flammable 10 m/s wind
CH4 flammable no wind
H2 flammable 10 m/s wind
H2 flammable no wind
The thermal energy of the released flammable gases is very different for methane and hydrogen due to the wider flammability limits of hydrogen (4 – 74% vol. conc.) compare to methane (5.3 – 15%).
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Numerical Setup 3-D Simulation
Grid discritisation and domain decomposition for parallel computingTotal grid with 3.5 mio. cells run on 16 CPU’s or 8 CPU’s
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3-D methane release and dispersion simulation
121 kg/s methane release rate corresponds to 6 GW thermal power
4 % molar conc. Isosurface10 m/s wind
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Flammability limits of methane within the release
About 10% to 30% of the released methane within the flammability limits
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3-D hydrogen release and dispersion simulation
4 % molar conc. Isosurface10 m/s wind
42.2 kg/s hydrogen release rate corresponds to 5 GW thermal power
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Flammability limits of hydrogen within the release
About 70% of the released hydrogen within the flammability limits
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Comparison of thermal energy released between methane and hydrogen for 3-D
0.E+00
1.E+07
2.E+07
3.E+07
4.E+07
5.E+07
6.E+07
0 1 2 3 4 5 6 7 8 9
Time [s]
En
erg
y [K
J]
H2 total released 10 m/s wind
H2 flammable 10 m/s wind
CH4 total released 10 m/s wind
CH4 flammable 10 m/s wind
The thermal energy of the released gases is similar for methane and hydrogen also in 3-D but again differs quite a lot for the gases within the flammability limits.
16 JRC – IE Pisa on 8.9.2004
Conclusions
1. Accidental releases from a methane and hydrogen pipeline have been modelled and compared for a scenario with and without wind.
2. Although the amount of total released energy is similar for methane and hydrogen, the amount of flammable hydrogen is larger than methane in all cases due to the wider flammability limits of hydrogen.
3. Due to the larger density of methane, methane might be more easily accumulated close to the ground under certain conditions (wind and geometric configuration) than hydrogen.
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18 JRC – IE Pisa on 8.9.2004
Governing Equations for Fluid Flow
0 = U)+)
(( t
Mass
B + τ)( + - = UU)+U) pt
((Momentum
Species iiii YYt
+J = )U+) ((
Energy hSt
phh
t
d
d(( + Uτ +q = )U+)
19 JRC – IE Pisa on 8.9.2004
Gas Dispersion in HyJet Jx7
Iso surface of 15% Vol. He colored with turbulent intensity at 200 s
The HyJet experiments will be used to validate a CFD-Code for dispersion modelling. The experiments were performed in the Battelle-Model-Containment. Within the experiments Helium is release through a nozzle in one of the lower so called banana rooms. After the release a Helium stratified atmosphere is developed in the upper part of the containment.In HyJet Jx7 Helium is released through a 9.5 cm nozzle at a speed of 42 m/s for 200 s.
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HyJet Jx7 comparison with experiment
Axial profile through jet axis 190 s after the beginning of injection
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New High Performance Computing Hardware
The CURIE High Performance Computing Cluster is installed with a total of 50 CPU’s. The System has a performance of 128 GFLOPS (billion floating point operations per second) being by fare the most powerful computing system in the JRC.
The system is used for hydrogen safety studies, for safety studies of new innovative nuclear reactors and for modelling of material failure on very small scale (crystal modelling) and other applications demanding high performance computing power.
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HPC load on CURIE last month (2/2)
Performance of the cluster via web interface (individual compute nodes)
23 JRC – IE Pisa on 8.9.2004
HPC load on CURIE last month (1/2)
Performance of the cluster via web interface