Hydrogen Integration in Petrochemical Complexes, Using Modified Automated Targeting Method
Owing to extensive use of hydrogen in refining or
petrochemical units, it is essential to manage hydrogen network in
order to make the most efficient utilization of hydrogen. On the other
hand, hydrogen is an important byproduct not properly used through
petrochemical complexes and mostly sent to the fuel system. A few
works have been reported in literature to improve hydrogen network
for petrochemical complexes. In this study a comprehensive analysis
is carried out on petrochemical units using a modified automated
targeting technique which is applied to determine the minimum
hydrogen consumption. Having applied the modified targeting
method in two petrochemical cases, the results showed a significant
reduction in required fresh hydrogen.
[1] Alves, J.J., Towler, G.P., "Analysis of refinery hydrogen distribution
systems," Industrial & Engineering Chemistry Research 41, pp. 5759-
5769, 2002.
[2] El-Halwagi, M., Gabriel, F., Harell, D., "Rigorous graphical targeting
for resource conservation via material recycle/reuse networks,"
Industrial & Engineering Chemistry Research 42, pp. 4319-4328, 2003.
[3] Foo, D.C.Y., Mannan, Z.A., "Setting the minimum utility gas flowrate
targets using cascade analysis technique," Industrial & Engineering
Chemistry Research, vol. 45, pp. 5986-5995, 2006.
[4] Hallale, N., Liu, F., "Refinery hydrogen management for clean fuels
production," Advances in Environmental Research 6, pp. 81-98, 2001.
[5] Liu, F., Zhang, N., "Strategy of purifier selection and integration in
hydrogen networks," Chemical Engineering Research & Design, vol. 82,
pp. 1315-1330, 2004.
[6] Ahmad, M.I., Zhang, N., Jobson, M., "Modelling and optimisation for
design of hydrogen networks for multi-period operation," Journal of
Cleaner Production, vol. 18, pp. 889-899, 2010.
[7] Ng, D.K.S., Foo, D.C.Y., Tan, R.R., "Automated targeting technique for
single- impurity resource conservation networks. Part 1: Direct
reuse/recycle," Indus- trial & Engineering Chemistry Research, vol. 48,
pp. 7637-7646, 2009a.
[8] Ng, D.K.S., Foo, D.C.Y., Tan, R.R., "Automated targeting technique for
single- impurity resource conservation networks. Part 2: Single-pass and
partitioning waste-interception systems," Industrial & Engineering
Chemistry Research, vol. 48, pp. 7647-7661, 2009b.
[9] M. M. El-Halwagi, V. Manousiothakis, "Automatic Synthesis of Mass-
Exchange Networks with Single Component Targets," Chem. Eng. Sci.,
vol. 9, pp 2813-2831, 1990.
[10] Brooke, A., Kendrick, D., Meeruas, A., Raman, R., GAMS-Language
Guide. GAMS Development Corporation, Washington, D.C., 2006.
[1] Alves, J.J., Towler, G.P., "Analysis of refinery hydrogen distribution
systems," Industrial & Engineering Chemistry Research 41, pp. 5759-
5769, 2002.
[2] El-Halwagi, M., Gabriel, F., Harell, D., "Rigorous graphical targeting
for resource conservation via material recycle/reuse networks,"
Industrial & Engineering Chemistry Research 42, pp. 4319-4328, 2003.
[3] Foo, D.C.Y., Mannan, Z.A., "Setting the minimum utility gas flowrate
targets using cascade analysis technique," Industrial & Engineering
Chemistry Research, vol. 45, pp. 5986-5995, 2006.
[4] Hallale, N., Liu, F., "Refinery hydrogen management for clean fuels
production," Advances in Environmental Research 6, pp. 81-98, 2001.
[5] Liu, F., Zhang, N., "Strategy of purifier selection and integration in
hydrogen networks," Chemical Engineering Research & Design, vol. 82,
pp. 1315-1330, 2004.
[6] Ahmad, M.I., Zhang, N., Jobson, M., "Modelling and optimisation for
design of hydrogen networks for multi-period operation," Journal of
Cleaner Production, vol. 18, pp. 889-899, 2010.
[7] Ng, D.K.S., Foo, D.C.Y., Tan, R.R., "Automated targeting technique for
single- impurity resource conservation networks. Part 1: Direct
reuse/recycle," Indus- trial & Engineering Chemistry Research, vol. 48,
pp. 7637-7646, 2009a.
[8] Ng, D.K.S., Foo, D.C.Y., Tan, R.R., "Automated targeting technique for
single- impurity resource conservation networks. Part 2: Single-pass and
partitioning waste-interception systems," Industrial & Engineering
Chemistry Research, vol. 48, pp. 7647-7661, 2009b.
[9] M. M. El-Halwagi, V. Manousiothakis, "Automatic Synthesis of Mass-
Exchange Networks with Single Component Targets," Chem. Eng. Sci.,
vol. 9, pp 2813-2831, 1990.
[10] Brooke, A., Kendrick, D., Meeruas, A., Raman, R., GAMS-Language
Guide. GAMS Development Corporation, Washington, D.C., 2006.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:63149", author = "M. Shariati and N. Tahouni and A. Khoshgard and M.H. Panjeshahi", title = "Hydrogen Integration in Petrochemical Complexes, Using Modified Automated Targeting Method", abstract = "Owing to extensive use of hydrogen in refining or
petrochemical units, it is essential to manage hydrogen network in
order to make the most efficient utilization of hydrogen. On the other
hand, hydrogen is an important byproduct not properly used through
petrochemical complexes and mostly sent to the fuel system. A few
works have been reported in literature to improve hydrogen network
for petrochemical complexes. In this study a comprehensive analysis
is carried out on petrochemical units using a modified automated
targeting technique which is applied to determine the minimum
hydrogen consumption. Having applied the modified targeting
method in two petrochemical cases, the results showed a significant
reduction in required fresh hydrogen.", keywords = "Automated targeting, Hydrogen network,
Petrochemical, Process integration.", volume = "6", number = "5", pages = "486-8", }