CET 96
DOI: 10.3303/CET2296017
Paper Received: 30 November 2021; Revised: 25 June 2022; Accepted: 13 September 2022
Please cite this article as: Bozzoli L., Cipolletta M., Casson Moreno V., Cozzani V., 2022, Analysis of an Integrated Energy System Aimed at the
Offshore Production of Methanol, Chemical Engineering Transactions, 96, 97-102 DOI:10.3303/CET2296017
CHEMICAL ENGINEERING TRANSACTIONS
VOL. 96, 2022
A publication of
The Italian Association
of Chemical Engineering
Online at www.cetjournal.it
Guest Editors: David Bogle, Flavio Manenti, Piero Salatino
Copyright © 2022, AIDIC Servizi S.r.l.
ISBN 978-88-95608-95-2; ISSN 2283-9216
Analysis of an Integrated Energy System Aimed at the
Offshore Production of Methanol
Leonardo Bozzoli*, Mariasole Cipolletta, Valeria Casson Moreno, Valerio Cozzani
Alma Mater Studiorum - Università di Bologna, Dipartimento di Ingegneria Civile, Chimica, Ambientale e dei Materiali, via
Terracini 28, 40131 Bologna, Italy
leonardo.bozzoli@unibo.it
The results of the offshore integration of fossil and renewable energy sources (RESs) to produce an energy
vector, namely methanol, are discussed. The methodology developed and hereby presented, allowed at first
the selection of the best technology for offshore RESs exploitation, where a near-to-decommissioning platform
is used as an energy hub. Based on the availability of natural gas from the depleted reservoir, the most suitable
process for offshore methanol production was chosen among various alternative innovative processes. The
optimal mix for energy production was then identified by varying the number of converters for each RES. Finally,
the methanol production process was designed on the basis of the available electric power, including a backup
system based on natural gas, to perform RESs valley filling and to achieve a steady state process.
1. Introduction
The decommissioning of an offshore platform is the final step in its life cycle and consists of the total or partial
removal of the installation, a technically complex and highly impacting process from both the environmental and
economic standpoints (ICF International, 2015). Moreover, in the exploited reservoir, fossil sources may still be
present, even if their production and transport to the shore may be not economically viable due to their low
pressure or low flow rate, as for the case of strained offshore platforms (Tan et al., 2021).
The high number of decommissioning offshore platforms, e.g. 5048 in 2017 in the Gulf of Mexico (Kaiser, 2019)
and 48 in 2021 in the United Kingdom Continental Shelf (UK) in the North Sea (GOV.UK, 2022), can be an
opportunity to re-use structures for other applications (Ministry of Economic Development, 2019), for example,
to create a hub for the production of renewable energy and synthetic fuels or energy vectors (Crivellari and
Cozzani, 2020). Indeed, to produce energy vectors, carbon substrates are needed and some may be taken from
the reservoir.
The offshore context represents an opportunity for the exploitation of RESs as wind, wave, tidal and sun, with
several advantages compared to the onshore context, for example, a more stable energy intensity, a higher
energy density and the availability of space without subtracting land for other uses (Dincer et al., 2021).
Among all energy vectors, methanol is one of the most promising (Schorn et al., 2021), thanks to its low carbon
content and its physical characteristics at atmospheric conditions. Besides, it can also be used as a fuel, either
blended with gasoline in conventional internal combustion engines or alone with minor devices modifications.
Last but not least, methanol is a precursor largely used in the chemical and process industry (PubChem, 2022).
In the literature, to the best of authors knowledge, there is not a comprehensive approach for the design of
energy systems integrating the RESs available around an offshore platform to be exploited in the framework of
Power to Liquid (P2L) processes. Yang et al. (2018) designed a gas-to-methanol process based on integration
among methane, electricity and wind turbines to provide energy for the process. However, the study focused
mostly on process design and carbon efficiency calculation.
The aim of the present study was the development of a new methodology to optimize renewable energy
production from different RESs to support offshore methanol production through an innovative process. The
proposed methodology was then applied to a case study (i.e. an offshore gas platform located in the north
Adriatic Sea with natural gas residual flowrate). The following assumptions were made in the definition of the
case study: the process energetic self-sustainability was reached through the available RESs (i.e. wind, wave
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and sun) and the backup system, supposed to be fed by fossil fuels. The management of the electrical power
excess produced by converters was considered out of scope of the present study, that focused on the
assessment of the methanol production system.
2. Methodology
In this paragraph the methodology developed to obtain an optimized hybrid energy system for the self-sustained
offshore production of methanol is described. It was divided into five steps, as shown in Figure 1.
At step 1, the offshore site has to be chosen and some considerations have to be done to drive this choice.
Firstly, the choice of the site is related to the presence of a platform close to the decommissioning-phase;
secondly, as reported in literature (Crivellari et al., 2021), CO2 or CH4 are needed as precursors to produce
methanol through innovative processes, thus other important aspects were the composition and the flowrate of
the residual gas from the reservoir. Actually, in case natural gas is not present in a sufficient amount, it had to
be imported or produced on the platform. The last phase of the first step consists in checking the availability of
meteo-climatic data related to the different RESs. Data collected must cover at least one year to investigate all
seasonal variations, while timestep has to be one hour or lower due to RESs unpredictability.
The second step is the elaboration of the collected data to evaluate the energy potential of each source in the
site. After that, the optimal converter is selected for each source, considering the potentiality and the operating
conditions for which the converter was designed.
The third step is the calculation of the power production curves, according to both collected data and converters
performance. For the solar power production, equations reported in (UNI, 2016) were used. The powers
produced by the wind turbine (WT) and by the wave energy converter (WEC) are calculated using respectively
power curve (Napolitano, 2021) and power matrix (Lejerskog et al., 2015) (as shown in section 4 of the present
paper), two tools provided by constructors and specific for each converter. The tools work getting as input one
or more site variables and providing in output the power produced by the converters; the input needed for the
power curve is the wind speed while inputs needed for the power matrix are Hs (significant wave height, in m)
and Te (equivalent wave period, in s).
The fourth step of the methodology consists of (i) the elaboration of power production curves by each converter
to determinate the optimal converters mix and (ii) the determination of process potentiality, two aspects strictly
interconnected; indeed, given a mix of converters, a process characterized by a higher production capacity
requires a more powerful backup system to act when RESs cannot sustain the process, resulting in a higher
fossil fuel consumption. The elaboration of power production curves consisted on dividing the power produced
by each converter in power classes, (e.g. class 1: 0-2 kW, class 2: 2-4kW,..), in order to identify: (i) the number
of hours of power production per each power class, (ii) the number of hours of no power generation and (iii) the
most frequent power class of power production for each converter as to evaluate the contribute that each
converter could bring to the mix. Then, two parameters are calculated for several converters combinations and
several power-thresholds related to the synthesis process, based on previous calculations: the number of hours
in which converters are not able to fully sustain the process and the average power to be supplied to the process
by the backup system during these time periods. The aim is to find the optimal compromise between the
potentialities of the renewable generation system and of the methanol process, to reach the lowest fossil fuel
utilization without oversizing the converters mix.
After determining the plant size, the last step consists in the conceptual design of the process through a software
such as Aspen HYSYS. The design is implemented considering the offshore environment constraints (e.g. the
temperature of seawater, if used as cooling). Then, the backup system is also designed, choosing the most
Figure 1: schematic representation of the proposed methodological steps.
Step 1
Site selection and data
collection
Site potentiality evaluation
and choice of the energy
converters
Hourly generation output of
each converter
Output elaboration to
determinate converters mix
and plant potentiality
Conceptual process design
and design of the backup
system
Step 2 Step 3
Step 5Step 4
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suitable option for the context, considering the available fossil sources and the nature of power required by the
process (i.e. thermal or electric).
3. Case study characterization
To demonstrate the application of the proposed approach, an offshore natural gas platform in the Adriatic Sea
was used as a case-study. The platform selected is Garibaldi C (Ministery of ecologic Transition, 2020), located
18 km off the coast of Ravenna, in the North Adriatic Sea. The choice was driven by two main reasons: (i) the
availability of data of the flowrate natural gas and its composition (i.e. 846 kmol/d of almost pure methane)
(Gamna, 2019), and (ii) the availability of data related to the exploitable RESs, provided by a metric wave buoy
called Nausicaa, located 5.3 km from Ravenna coast.
The energy vector production process was selected starting from an accurate literature analysis focused on
innovative processes for methanol synthesis. In the study by Crivellari et al. (2021), eleven innovative processes
were reported. Nine of them are based on partial oxidation of methanol, while the others two are based on CO2
hydrogenation. Given the reservoir fluid (high amount of CH4 and low amount of CO2) the process selected for
methanol production was methane-based. Among all, the best option was the radical partial oxidation of
methane in gaseous phase (Yarlagadda et al., 1988) thanks to its high yield (7.22 %), selectivity (76 %) and
final concentration (6.6 % mol).
4. Results and discussion
Once the offshore platform was selected, the data for the exploitable RESs in the area were collected (according
to step 1 of Figure 1). Sun, wind and wave energy were considered in the present study. The related hourly data
were downloaded for a representative year (i.e. 2017). As mentioned in the previous paragraph, wave data
collected from a metric wave buoy (Nausicaa) were obtained from the“Dext3r” database (Arpae, 2019). For solar
radiation and wind speed (at the heights of 10 and 100 m, respectively) the European Centre for Medium-Range
Weather Forecast (ECMWF, 2022) database was used.
The potentialities for each RES were calculated according to step 2 of the methodology. For the case of solar
energy, total irradiation on a surface with optimal tilt (34°) was calculated equal to 5950 kJ/m2/y (the average
irradiation from North to South in Italy ranges from 3500 kJ/m2/y to 6700 kJ/m2/y) (European Commission, 2022).
After data elaboration for the two heights, Weibull distribution showed a low energy density: the yearly average
wind speed at 10 m was 2.95 m/s and 4.21 m/s at 100 m height. Regarding the wave energy potential, the yearly
average power was 1.02 kW/m, an extremely low value (Mørk et al., 2010). After the potentiality estimation, the
second phase of step 2 consisted of the selection of energy converters. The high-efficiency photovoltaic (PV)
panel called Maxeon 3 400 W (SunPower, 2019) was chosen. The WT choice was directed to the Goldwind
GW/1500 PMDD (Goldwind, 2015), with a hub height of 85 m able to exploit the higher speeds at higher height,
with a cut-in of 2.5 m/s, a parameter which enables to better exploit the low potentiality. The most suitable WEC
for the given wave motion conditions was the L9 Lysekil (Lejerskog et al., 2015), a point absorber with a
maximum power output of about 20 kW and a cut-in of Hs = 0.25 m and Te = 2.5 s.
At step 3, the energy and the power produced from each single converter were calculated (as reported in Table
1). PV panels production was calculated considering 949 m2 (platform area available for panels installation).
Using the power curve of the WT (Figure 2b), for a given average hourly velocity, the average hourly power
output was determined. A similar procedure was carried out for the point absorber converter, using data of Hs
and Te as input for the power matrix (Figure 2a) (Hong et al., 2016).
Figure 2: (a) L9 point absorber power matrix; (b) Goldwing WT power curve.
a) b)
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Table 1: Converters peak power and energy generation data in the studied year.
Converter Peak power [kW] Annual energy [MWh/y] Yearly average power [kW]
PV panel 215 283 32.4
WT 1500 2580 294
WEC 20 5 0.58
In Figure 3, data of each converter elaborated as described in step 4 of the methodology are presented. Higher
power class corresponds to higher power produced. The WEC and PV panels do not produce power for about
half of the time. The WEC has the highest percentage of operating time in the two lowest power classes, due to
low wave potentiality. The PV panels showed an increasing power production for increasing power classes. WT
was the most operative converter due to a relatively low time of non-energy production (27 %). Then, to achieve
the maximum exploitation of RESs without oversizing the converters mix (and therefore the backup system), in
the second phase of step 4 several combinations of converters and process sizes were considered, as shown
in Table 2. Four plant potentialities (60, 100, 200, 400 kW) and 4 converters combinations for the hybrid energy
system (949 m2 PV panels, 1 or 3 WTs, 10, 50 or 100 WECs) were considered. The number of hours in which
the back-up system had to sustain (partially or fully) the process and the average power needed in those hours
were calculated for each combination. Considering the results shown in Table 2, a configuration characterized
by 60 kW of power available for the methanol process and sustained by 949 m2 of PV panels, 1 WT and 50
WECs was selected as optimal.
The fifth step was the process conceptual design starting from data reported in the literature (Yarlagadda et
al.,1988). This step was carried out with Aspen HYSYS, obtaining both data regarding methanol production and
required energy. An iterative process consisting in scaling HYSYS output data was carried out to size the
process with the chosen potentiality, considering 10 % of power for auxiliaries. The final sizing resulted in 60
kW consisting of: 43.25 kWt, 11.30 kWe and 5.45 kWe for auxiliaries. Methanol produced with 60 kW was 389
kg/d. The process flow sheet is shown in Figure 4. As expected, the power production of the proposed mix was
not able to cover 100 % of the process energy requirements: 625 hours (7 % of the total running time) were not
covered by the RESs.
Figure 3: Power classes generation performance of each conversion device: (a) WT; (b) PV panels; (c) WEC.
Per each power class, the power fraction produced on a yearly basis and the yearly generation frequency are
displayed.
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Table 2: Possible configurations for the hybrid energy system. NE means not enough and P̅ is the average
power to be supplied in the respective associate hours.
Configuration Plant potentiality
60 kW 100 kW 200 kW 400 kW
949 m2, 1 WT 1500, 10
WEC
n hours NE
P̅ [kW]
2279
42.8
3227
64.1
5029
126.3
6607
276.2
949 m2, 1 WT 1500, 50
WEC
n hours NE
P̅ [kW]
2121
41.4
3060
62.4
4902
123.3
6499
272.1
949 m2, 1 WT 1500, 100
WEC
n hours NE
P̅ [kW]
2011
40.0
2876
61.7
4739
120.8
6366
268.1
949 m2, 3 WT 1500, 100
WEC
n hours NE
P̅ [kW]
1655
42.0
2207
67.0
3333
130.0
4443
274.0
The appropriate backup system had to be chosen given the energy requirements of the facilities (43.25 kWt,
16.75 kWe). A Combined Heat and Power generator Microturbine was chosen as a suitable system, and after
checking the possible heat recovery from the exhaust stream, a microturbine with 30 kWe and 60 kWt of
maximum power output was selected. Considering 2121 h/y of operation during which it has to partially or fully
sustain the process (24.2 % of the year), with an average power supply of 41.4 kW, the backup system will
consume 17950 kg of methane. This corresponds to 0.36 % of the amount extracted yearly from the well (at
nominal potentiality, the micro-turbine would use 1.5 % of the total natural gas flow rate) and it will provide 16.7
% of total energy to the process.
The approach presented was applied to a case study chosen accordingly to the platform characteristics.
However, it is important to remark that the RESs potentiality are very low in the geographical area considered.
This was in part due to the position of the buoy, located at 5.3 km from the coast (the platform is 18 km from the
coast), determining a lower density of wind and wave energy (Esteban et al., 2011). Also, the macro area had
a negative influence on the process potentiality: indeed, the intake of wind and waves could be more significant
in areas as the North Sea, or even more in oceans where the energy density of considered RESs is significantly
higher.
5. Conclusions
This study aimed to prove the feasibility of an offshore hub for the production of methanol as energy vector
using a hybrid fossil-RESs energy system. A case study to demonstrate the methodology is reported. Starting
from the site selection, data of solar radiation, wind speed and wave characteristic were collected to evaluate
the RESs potentiality. Then, converters for each RESs were selected. The nominal power of the integrated
Figure 4: process scheme considered for the HYSYS simulations of methanol production.
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renewable system and the size of the coupled methanol plant were found maximising the energy independence
of the facility. After this, a back-up system was designed. Despite the low energy density of RESs in the site,
the production of methanol was not negligible. The converter mix provided a satisfying power continuity showing
a good integration of different RESs, limiting the operating time of the necessary backup system. On a more
general basis, the approach presented provides a method to support decision making concerning offshore RESs
exploitation re-using decommissioning platforms.
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Analysis of an Integrated Energy System Aimed at the Offshore Production of Methanol