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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 39, 2014 

A publication of 

 
The Italian Association 

of Chemical Engineering 

www.aidic.it/cet 
Guest Editors: Petar Sabev Varbanov, Jiří Jaromír Klemeš, Peng Yen Liew, Jun Yow Yong  

Copyright © 2014, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-30-3; ISSN 2283-9216 DOI:10.3303/CET1439181 

 

Please cite this article as: Nguyen T.V., Tock L., Breuhaus P., Maréchal F., Elmegaard B., 2014, Thermo-economic 

modelling and process integration of CO2-mitigation options on oil and gas platforms, Chemical Engineering Transactions, 

39, 1081-1086  DOI:10.3303/CET1439181 

1081 

Thermo-Economic Modelling and Process Integration of 

CO2-Mitigation Options on Oil and Gas Platforms 

Tuong-Van Nguyen*
a
, Laurence Tock

b
, Peter Breuhaus

c
, François Maréchal

b
, 

Brian Elmegaard
a
 

a
Section of Thermal Energy, Department of Mechanical Engineering, Technical University of Denmark, Building 403, 

Nils Koppels Allé, 2800 Kongens Lyngby, Denmark 
b
Industrial Process and Energy Systems Engineering Laboratory, École Polytechnique Fédérale de Lausanne,  

Station postale 9, 1015 Lausanne, Switzerland 
c
Energy Department, International Research Institute of Stavanger, Professor Olav Hanssens vei 15, 4021 Stavanger, 

Norway 

tungu@mek.dtu.dk  

The offshore extraction of oil and gas is an energy-intensive process associated with large CO2 and CH4 

emissions to the atmosphere and chemicals to the sea. The taxation of these emissions has encouraged 

the development of more energy-efficient and environmental-friendly solutions, of which three are 

assessed in this paper. The integration of steam bottoming cycles on the gas turbines or of low-

temperature power cycles on the export gas compression can result either in an additional power output, 

or in a greater export of natural gas. Another possibility is to implement a CO2-capture unit, which allows 

recovering CO2 that can be used for enhanced oil recovery. In this paper, a North Sea platform is 

considered as case study, and the site-scale retrofit integration of these three options is analysed, 

considering thermodynamic, economic and environmental performance indicators. The results illustrate the 

benefits of valorising the waste heat recovered from the exhaust gases, as the total CO2-emissions can be 

reduced by more than 15 %. Exploiting low-temperature heat seems feasible, although more challenging in 

retrofit situations. Integrating CO2-capture appears promising with a CO2-avoidance cost between 23 and 

29 $/tCO2 for the chosen economic assumptions.   

1. Introduction 

The extraction and processing of oil and gas on offshore fields is an energy-intensive sector that 

represented up to 26 % of the total CO2-emissions of Norway in 2011. These emissions are caused by the 

combustion of diesel, gas or oil for on-site power generation and are subject to a hydrocarbon fuel tax that 

has increased the last years, from 210 ($ 35) to 410 NOK ($ 67) per ton of CO2 (Norwegian Ministry of 

Petroleum, 2012). In this context, reducing the CO2 emissions has become more and more interesting 

from both an environmental and an economic prospective. This goal can be achieved (i) by improving the 

performance of the oil processing plant with a low-temperature waste heat recovery cycle (Rohde, 2013), 

(ii) by increasing the efficiency of the power generation plant with a steam network (Kloster, 1999), by (iii) 

implementing a carbon capture unit, or by (iv) connecting offshore platforms to the mainland through 

electrical cables. Several studies dealing with the design of these processes can be found in the literature. 

However, at the knowledge of the authors, these technologies are generally optimised individually, and the 

literature lacks a systematic analysis of the site-scale integration of these processes. The different 

synergies should therefore be assessed thoroughly to enhance the performance of the overall plant. The 

objectives of the present work are to (i) evaluate the prospects for integrating steam bottoming cycles, low-

temperature cycles and CO2-capture processes on an existing oil and gas platform, (ii) assess the thermo-

environomic (i.e. thermodynamic, economic and environmental) performance, (iii) and identify the possible 

trade-off between competing objectives, by performing multi-objective optimisations. 

mailto:tungu@mek.dtu.dk


 
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2. Methodology 

2.1 System description 
Oil and gas platforms present similar structural designs but process petroleum with different characteristics 

(e.g. viscosity) and operate on fields with different properties (e.g. temperature, pressure, water- and gas-

to-oil ratios) (Manning, 1991). An oil and gas facility can be divided into two main sub-systems: the 

processing plant, where oil, gas and water are separated and treated, before being exported to the shore 

or rejected to the environment; and a utility plant, where the power and heat required for driving the 

separation and compression processes are produced.  

The different technological options, which can be implemented to reduce the CO2-emissions of the oil and 

gas plant, are investigated and included a process superstructure displayed in Figure 1. There are five gas 

turbines, of which three provide the power required in the processing plant, and the remaining two are run 

in case of water injection. The steam cycle is considered as a bottoming cycle to the main gas turbines 

(Kloster, 1999). The low-temperature cycles that are investigated in this work are based on carbon dioxide 

(trans-critical), propane (subcritical) and ethane-propane (trans-critical) mixtures as working fluids, 

following the study of Rohde et al. (Rohde, 2013). Since the turbine exhausts are rejected at low pressure 

(near-atmospheric) and have a low CO2-concentration, the CO2-removal step is achieved by chemical 

absorption with monoethanolamine (Tock, 2012). For a grass-root case, the integration of pre-combustion 

carbon capture and storage may be better, since the resulting equipment and the compression work would 

be smaller. Flue gases enter an absorption column in which an aqueous solution with alkanolamines, at a 

mass concentration of 30 - 35 %, flows counter-currently. The carbon dioxide is captured by scrubbing and 

chemical recombination into bicarbonate ions. The captured CO2 is then dehydrated and compressed to 

180 bar, as this is the required pressure for enhanced oil recovery when using gas.  

2.2 Thermo-economic modelling 
The methodology followed in this work has been extensively described in Bolliger et al. (2009), and has 

been extended to the design of other systems such as hydrogen production (see e.g. Tock et al. (2012)). 

The approach (Figure 2) relies on the combination of flow-sheeting techniques, energy integration models, 

economic evaluations using the correlations of Turton et al. (2012) and a multi-objective optimisation 

routine (Molyneaux, 2002), based on a genetic algorithm.  

The models of the oil and gas platform and of the CO2-capture by monoethanolamine are developed using 

the commercial flow-sheeting software Aspen Plus (Aspen Technology, 1999), and the modelling and 

 

 

Figure 1: Process superstructure of CO2-mitigation options for oil and gas platforms 



 
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Figure 2: Framework methodology for the modelling and optimisation of the CO2-mitigation options 

assumption details are presented in Nguyen et al. (2014) and Tock et al. (2012). The steam network is 

simulated, based on the work of Maréchal and Kalitventzeff (1997).  

The low-temperature power cycles are modelled with Belsim VALI (BELSIM Vali, 2010), using a piecewise 

linear parameterisation for the temperature-enthalpy profiles. The energy-integration model builds on the 

use of the pinch analysis technique (Linnhoff, 1989), considering individual temperature differences 

(ΔTmin/2) of 2 K, 4 K and 8 K for phase-changing, liquid and gas streams. This heat cascade problem is 

formulated as a Mixed Integer Linear Programming (MILP) problem, assessing precisely the heating and 

cooling requirements of the oil platform, and optimising the selection and use of the utilities (e.g. process 

water and seawater). The heating demand is satisfied by waste heat recovery from the turbine exhausts, 

while the cooling demand is met by processing seawater or recovering cooling water from the processing 

plant. The economic model builds on the resulting state variables and system operating conditions, 

calculating the costs with the capacity-based correlations of Turton et al. (Turton, 2012), which have an 

uncertainty of about 30 %. An operation of 95 %, a lifetime of 15 y and an interest rate of 10 % are 

considered.  

2.3 Performance indicators 

The overall performance can be evaluated by a large variety of thermodynamic and economic indicators, 

and this study focuses on:  

(i) The energy intensity of the facility σ, defined as the ratio of the energy used on-site in form of fuel gas, 

to the energy exported to the shore with oil and gas; 

(ii) The energy efficiency of the cogeneration plant η, defined as the ratio of the energy transfers with heat 

and power (steam network and gas turbines), to the energy used as fuel gas;  

(iii) The additional investment costs Cinv, which are associated with the implementation of a steam cycle, a 

low-temperature power cycle and a CO2-capture unit; 

(iv) The increase of natural gas δNG exported to the shore; 

(v) The reduction of CO2-emissions δCO2 caused by the decrease of fuel gas consumption and the possible 

integration of a CO2-mitigation plant; 

(vi) The changes in operating costs Cop, due to the replacement of monoethanolamine because of 

degradation issues; 

(vii) The CO2-avoidance cost CAC, defined as the ratio of the increase in investment costs over the 

decrease of CO2-emissions; 

(viii) The power capacity of the additional systems P.        

2.4 Multi-objective optimisation 

Several objectives can be considered, based on the numerous performance indicators: they illustrate that 

decision-makers need to evaluate the trade-offs between two or more competing objectives (e.g. limitation 



 
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of the investment costs versus reduction of CO2-emissions). The objectives considered in the optimisation 

procedure are the maximisation of the power capacity P, the minimisation of the investment costs Cinv and 

the maximisation of the reduction of the local CO2-emissions δCO2. The optimal system configurations are 

computed by performing a multi-objective optimisation and displaying the solutions under the form of a 

Pareto optimal frontier. The master decision variables amount to 48, of which 18 are related to the 

operation of the steam cycle (e.g. pressures, temperatures, vapour fraction), 5 to the selection of the 

cooling utility (e.g. process water and temperatures), 12 to the selection and design of the low-temperature 

power cycle (e.g. superheating approach), and 13 to the configuration of the CO2-capture unit (e.g, 

equipment sizes and operating conditions).  

3. Results and discussion 

3.1 Baseline case 

The current system is characterised by a power demand of about 19 MW, a heating demand smaller than 

5 MW and a cooling demand greater than 30 MW, which is met by processing more than 2,000 m
3
/h of 

seawater at about 8 °C and lifted onsite. The pinch point of the overall facility is located at about 150 °C, 

illustrating that most heat discharged to the environment is at low (under 100 °C) temperatures. The 

heating demand, between 150 and 230 °C, is satisfied by recovering heat from the exhaust gases at about 

330 °C. The thermal efficiency of the gas turbines varies between 23 % (current operating point) to 34 % 

(nominal design point), and the energy intensity σ amounts to 4.6 %. The total daily CO2-emissions 

produced locally reach about 450 t, of which more than 90 % are emitted from the gas turbines.   

3.2 Optimal configurations 
The optimal solutions recovered from the multi-objective optimisation routine can be grouped into three 

clusters: Cluster 1, where only a steam network is integrated, Cluster 2, where a steam network and a low-

temperature cycle are integrated, and Cluster 3, where a steam network and a CO2-capture unit with 

monoethanolamine are implemented. The following trends can be observed.  

In general, the integration of a steam network allows for a greater power production P, ranging from 3 to 8 

MW at design conditions for a total investment cost Cinv from 6 to 14 M$. There are no further increases in 

operating costs, as no additional fuel is required, and the number of operators is assumed to be constant. 

The efficiency η increases to about 35-40 % when the steam cycle is run at full-load conditions, and 

between 28 and 33 % when run for the normal operating conditions. All the optimal steam cycles consist of 

a single production level at a pressure between 8 and 13 bar and a condensation level below 0.5 bar. The 

cooling utility used in the steam condenser is the process water, i.e. the cooling water from the processing 

plant at about 16.5 °C. The export of natural gas to the shore δNG increases by up to 14 %, and this goes 

along with a reduction of the CO2-emissions of up to 16 %. The CO2-avoidance cost CAC reaches about 

27-33 $/tCO2, which should be compared against the CO2-tax of about 67 $/tCO2. 

The integration of a low-temperature power cycle results in an additional power generation of up to 3.5 

MW, if heat can be recovered from all the coolers located in the gas recompression and compression 

sections. Although the heat exchangers are already installed, such solutions may be problematic as further 

retrofit of the pipeline connections and of the heat exchangers may be necessary. Setting the low-

temperature power cycle only on the after-cooler placed at the outlets of the gas treatment process may 

not be viable, because the gas flow through this heat exchanger is already small (lower than 2 kg/s) and is 

expected to decrease with time. The total investment cost Cinv ranges between 5 and 7 M$, and the 

preferred low-temperature cycle for these applications is the ethane-propane cycle, as suggested 

previously in the work of Rohde et al. (2013). As expected, the economic and environmental benefits 

related to the decrease of the fuel gas consumption are smaller, with δNG and δCO2 smaller than 8 % in all 

cases. The CO2-avoidance cost is higher than for the integration of a steam cycle, reaching about 31-36 

$/tCO2. 
Finally, integrating a CO2-capture plant seems more appropriate when it is performed in conjunction with a 

steam cycle. However, the energy penalty that is related to the thermal regeneration of the chemical 

sorbent, and which is pointed out in other studies, is not as significant in the present case. The heat 

required in the desorption column is provided by the cooling of the exhaust gases after the gas turbines 

and steam cycle, illustrating the positive synergy between the bottoming cycle and the CO2-capture plant. 

The power demand at normal operating conditions increases by about 12 %, as a consequence of the 

power demand for compressing the CO2 and pumping the monoethanolamine. The purity of the CO2-rich 

stream exceeds 97 % on a molar basis and the CO2-capture rate varies between 87 % and 93 %. The 

investment costs vary between 7 and 11 M$ for the CO2-plant solely. The CO2-avoidance cost varies thus 

between 23 and 29 $/tCO2, considering that the steam cycle is integrated with the CO2 capture plant.     



 
1085 

   

Figure 3: Balanced Grand Composite Curves for a steam network and monoethanolamine CO2-capture 

unit (left) and a combined steam cycle + low-temperature C2H6-C3H8 power cycle (right) 

The area between the Grand Composite Curve and the temperature axis (Figure 3) illustrates the exergy 

destruction taking place in the heat exchanger network. The integration of a steam cycle and a low-

temperature power cycle reduces the exergy destruction at both high and low temperatures. This 

illustrates the high thermodynamic performance of such an integrated system, combined with a total 

increase of gas export of about 22 % and a reduction of the CO2-emissions of 25 %. On the contrary, the 

integration of a steam cycle and a CO2-plant only reduces the exergy losses with the exhaust gases, 

taking place at a temperature of 100 to 330 °C. The total CO2-emissions of the platform can be reduced by 

up to 70 % when combining a steam cycle with an ethanolamine plant, the remaining emissions being 

caused by flaring and emissions from the secondary gas turbines on-site.  

The Pareto fronts (Figure 4) illustrate the trade-off between the maximum power capacity, the CO2-capture 

and the investment costs. A system where a CO2-capture plant is installed along with a steam cycle 

presents the greatest potential for CO2-reduction. However, this is performed at the expense of significant 

investment costs, of about 14-18 M$, which are compensated by the significant reductions in CO2-taxes, 

which amount to about 0.02 M$ per day. These investment costs vary with the facility on which the CO2-

capture plant is implemented. They do not include site-specific investment costs, which can vary in a range 

as wide as 10—96 M$ (Torp & Brown, 2005). 

 

 

Figure 4: Thermo-economic and thermo-environomic Pareto frontiers comparing the maximum power 

capacity (left) and the CO2-reduction potential (right) against the total investment cost 

The need for an additional power capacity on this platform needs to be investigated carefully: the total 

power demand may increase with time, as more water may be injected into the reservoir for an enhanced 



 
1086 

 
oil recovery. The combination of a steam cycle and a low-temperature waste heat recovery may not be 

interesting in practice, as it requires consequent retrofitting. On the contrary, the implementation of a 

steam network with a CO2-capture unit allows for greater power generation, if needed, as well as a smaller 

fuel gas consumption and higher thermal efficiency at part-load conditions. Considering the expected 

lifetime of this facility, this alternative may be interesting, and the operating constraints of the mono-

ethanolamine system should be evaluated carefully.  

4. Conclusions 

The site-scale integrations of steam bottoming cycles, low-temperature power cycles and CO2-capture 

processes are compared. All possible configurations are embedded in a superstructure process model, 

which are further optimised by process integration. Their competitiveness is evaluated, using performance 

criteria assessing thermodynamic, economic and environmental aspects. In all cases, the integration of a 

steam network is revealed to be profitable, with an increase of the power generation capacity of up to 8 

MW, a greater gas export of up to 16 % and a CO2-avoidance cost of 31 - 36 $/tCO2. The integration of 

low-temperature power cycles is more challenging, as it requires a more extensive retrofitting of the facility, 

while presenting a higher CO2-avoidance cost for a smaller power capacity. The present analysis suggests 

that CO2-capture from the exhaust gases is competitive, given the current CO2-tax (67 $/tCO2) on 

hydrocarbon fuels and the potential for sequestrating up to 70 % of the total CO2 emitted on the platform.     

Acknowledgements 

The funding from the Norwegian Research Council through the Petromaks programme, within the project 

2034/E30 led by Teknova, is acknowledged.   

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