(203s) Systematic Approach for Conceptual Process Design: Production of Styrene From Benzene and Ethylene

Systematic Approach for Conceptual Process Design:
Production of Styrene from Benzene and Ethylene

Stefano Cignitti¹, Stéphanie
Linnea Franck², Katarzyna
Kępa¹, Michele Mattei¹

steci@student.dtu.dk,
s072796@student.dtu.dk, s120534@student.dtu.dk, micu@kt.dtu.dk

¹Department of Chemical and
Biochemical Engineering, Technical University of Denmark, Building 229, Søltofts Plads, DK-2800 Kongens Lyngby, Denmark 

²BioBusiness and Innovation Platform, Copenhagen
Business School, Solbjerg Plads
3, DK-2000 Frederiksberg, Denmark

Abstract

Styrene monomer is a highly important and demanded commodity chemical
utilized for the production of a large range of
polymers and co-polymers including polystyrene, rubber, resin and latex. In
this work, a systematic method is utilized to design an economically feasible,
sustainable and environmentally acceptable process for the production of
styrene from benzene and ethylene. The conceptual process design was performed
in the MSc-level course ?Process Design: Principles
and Methods? at the Department of Chemical and Biochemical Engineering.

In the base case design, styrene is produced by a two step process,
which is extensively used in the industry. The first involves high-pressure
alkylation of ethylene and benzene into the intermediate product ethylbenzene. The latter subsequently undergoes
dehydrogenation into styrene. The by-product p-diethylbenzene
is converted into ethylbenzene by addition of
recycled benzene in a transalkylation reactor. Ethylbenzene is recovered along with styrene and the
compounds are purified in two sequences of distillation columns.

The systematic method is based on twelve sequential tasks. The first
three cover a detailed description of the raw materials, product and process as
well as flow sheet synthesis executed by hierarchical decomposition [1]. In
task 4, linear mass balance calculations are performed for the synthesized flow
sheet. In tasks 5-7, process conditions are specified and mass & energy
balance is performed using more rigorous models in order to obtain the base
case design. Subsequently, in tasks 8-9, sizing and costing are estimated. In
the final three tasks, the process is improved through heat integration,
sustainability and environmental impact analysis and process optimization.

A commercial simulator is used for verification and process simulation,
together with other computational tools: ICAS for property prediction, ECON
for cost estimation of the process [2], SustainPro
for sustainability analysis and bottleneck identification [3], LCSoft for lifecycle assessment [4].

The following results were obtained from the base case design. The
production rate is 500,000 metric tons per year with a yield of 0.6 kg product
per kg raw material. The annual revenue amounts to USD 80 million with
break-even after 4.5 years. The bottlenecks are the operating cost of a
compressor (69%) and the large steam utility of the heat exchangers (17%).
These have been overcome by heat integration and process optimization. The
total energy consumption amounts to 46.3 kJ per kg product. After heat
integration, the external utilities are reduced by 88%.

References:

[1] Douglas, J.,
?A hierarchical decision procedure for process synthesis?, AIChE
Journal, 31, 353-362, 1985.

[2] Peters, M. S., Timmerhaus,
K.D., West, R. E., ?Plant Design and Economics for Chemical Engineers?, McGraw-Hill,
2004.

[3]
Carvalho, A., Matos, H.A., Gani,
R., ?SustainPro-A tool for systematic process
analysis, generation and evaluation of sustainable design alternatives?, Computers
and Chemical Engineering, 50,
8-27, 2013.

[4] Piyarak,
S., ?Development of software for Life Cycle Assessment?, The Petroleum and
Petrochemical College, Chulalongkorn University,
Thailand, 2012.