Acta Polytechnica


https://doi.org/10.14311/AP.2021.61.0504
Acta Polytechnica 61(4):504–510, 2021 © 2021 The Author(s). Licensed under a CC-BY 4.0 licence

Published by the Czech Technical University in Prague

CO2 POWER CYCLE CHEMISTRY IN THE CV ŘEŽ
EXPERIMENTAL LOOP

Jan Berkaa, b, ∗, Jakub Vojtěch Balleka, b, Ladislav Velebila,
Eliška Purkarováb, Alice Vagenknechtováb, Tomáš Hlinčíkb

a Centrum výzkumu Řež s.r.o., Husinec-Řež, Hlavní 130, Řež, Czech Republic
b University of Chemistry and Technology Prague, Faculty of Environmental Technology, Department of Gaseous

and Solid Fuels and Air Protection, Technická 1905, Prague 6, Czech Republic
∗ corresponding author: Jan.Berka@cvrez.cz

Abstract. Power cycles using carbon dioxide in a supercritical state (sc-CO2) can be used in both
the nuclear and non-nuclear power industry. These systems are characterized by their advantages over
steam power cycles, e. g., the sc-CO2 turbine is more compact than the steam turbine with a similar
performance. The parameters and lifespan of the system are influenced by the purity of the CO2 in the
circuit, especially the admixtures, such as O2, H2O, etc., cause the enhanced structural materials to
degrade. Therefore, gas purification and purity control systems for the sc-CO2 power cycles should be
proposed and developed. The inspiration for the proposal of these systems could stem from the gas,
especially the CO2-cooled nuclear reactors operation. The first information concerning the CO2 and
sc-CO2 power cycle chemistry was gathered in the first period of the project and it is summarized in
the paper.

Keywords: Supercritical carbon dioxide, sc-CO2, power cycle chemistry, materials, purification, purity
control.

1. Introduction

The increase of the electric power consumption and the
CO2 emissions reduction requirements demand new
and effective energy sources. One way of increasing
the conversion of mechanical power to electric power
is by using carbon dioxide as a working medium in
the power cycle. Currently, the power cycles that are
based on supercritical CO2 (sc-CO2) have been inves-
tigated [1, 2]. Carbon dioxide becomes supercritical
above a critical temperature of 30.98 °C (304.13 K)
and above a pressure of 7.32 MPa [2].

Apart from the power industry, sc-CO2 has been
used in other technologies. As examples, the extrac-
tion [3, 4], dissolving [5, 6], nanoparticles prepara-
tion [7] and impregnation [8] could be mentioned.

The sc-CO2 power cycle’s efficiency of the conver-
sion of mechanical power to electric power may exceed
50 % as compared to the conventional steam power cy-
cle, which has a maximum efficiency of approximately
40 % [9, 10]. The efficiency of sc-CO2 increases within
the temperature range of 500–950 °C. Therefore, this
technology is suitable for power conversions in both
high temperature non-nuclear and nuclear technolo-
gies, including the generation IV nuclear reactors.
The technologies with a possible use of sc-CO2 cy-
cles are listed in Table 1 [11]. Another advantage
of the sc-CO2 cycles is that they use more compact
turbines as compared to the turbines for the steam
power cycle [12].

2. R&D in sc-CO2 technologies
For sc-CO2 power cycles, several experimental devices
as well as pilot plants can be investigated and verified.
One of the larger devices is unit EPS100, which mea-
sures the exhaust heat usage in Echogen, USA. The
power output of this unit reaches seven to eight MW.
The optimum temperature of the source is 500-550 °C,
and the minimum source temperature is 85 °C, which
allows the low potential exhaust heat to be used [9].

Examples of smaller scale experimental units are as
follows:

• Supercritical CO2 Brayton Cycle Integral Experi-
ment Loop (SCIEL), South Korea

• Experimental loop Knolls Atomic Power Laboratory
(KAPL), USA

• Experimental loop Institute of Applied Energy
(IAE), Japan

• sc-CO2 loop SCARLETT (IKE) University of
Stuttgart, Germany

See ref. [9] for details.
In Centrum výzkumu Řež s.r.o. (Czech Republic),

the supercritical carbon dioxide experimental loop
has recently been built (see the scheme of the loop in
Figure 1). The purpose of the loop is to measure the
thermohydraulic performance and physical parameters
of the sc-CO2 circuits. Because the loop is equipped
with a test section, the loop can also be used for
testing materials.

504

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vol. 61 no. 4/2021 CO2 power cycle chemistry in the CV Řež . . .

Application Cycle type Advantages Output Temperature Pressure(MWe) (°C) (MPa)

Nuclear Indirectheating

Efficiency,

10-300 350-700 20-35compactness,reduced water
consumption

Fossil power
stations

Indirect
heating

Efficiency,
300-600 550-900 15-35reduced water

consumption

Fossil fuels
(synthesis and
natural gas)

Direct
combustion

Efficiency, reduced

300-600 1100-1500 35water consumption,carbon capture
storage

Thermal solar
power stations

Indirect
heating

Efficiency,

10-100 500-1000 35compactness,reduced water
consumption

Marine propulsion Indirectheating
Efficiency, < 10 200-300 15-25compactness,

Exhaust heat usage Indirectheating

Efficiency,
1-10 < 230-650 15-35compactness,

simplicity

Geothermal Indirectheating Efficiency 1-50 100-300 15

Table 1. Possible use of sc-CO2 power cycles [5].

Figure 1. Scheme of the supercritical carbon dioxide experimental loop at CV Řež. 1: low temperature heat
exchanger, 2: preheater, 3: main circulation pump, 4: cooler, 5: CO2 dosing system, 6: sampling system, 7: high
temperature heat exchanger, 8: cooler, 8, 9: heaters, 10: test section, 11: reduction valve, 12: cooler.

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J. Berka, J. V. Ballek, L. Velebil et al. Acta Polytechnica

Maximum medium temperature 550 °C
Maximum pressure in the high-pressure section 25 MPa
Maximum pressure in the low-pressure section 12.5 MPa
Maximum flow rate 0.4 kg·s−1

The loop volume 0.08 m3

Table 2. The main parameters of the supercritical carbon dioxide experimental loop at Centrum výzkumu Řež s.r.o.

Component
Natural gas Synthesis gas

(vol. %) (vol. %)

CO2 91.80 95.61
H2O 6.36 2.68
O2 0.20 0.57
N2 1.11 0.66
Ar 0.53 0.47

Table 3. Examples of the medium composition in the turbine inlet for the direct combustion cycle, according to the
used fuel [13, 14].

For the main parameters of the loop, see Table 2.
The function of the loop could be described as follows:
after the passage through the heat exchanger in the
high-pressure section (7), CO2 flows to two parallel
(8) and one serial (9) heater branches. After heating,
the medium flows to the test section (10). A reduction
valve (11) , which reduces the medium pressure to
12.5 MPa, is placed after the test section. Due to the
accurate temperature reduction, a part of the flow is
passed through the oil cooler (12), and the second
part flows through the bypass. Following that, the
medium reaches the low-pressure part of the high tem-
perature heat exchanger (7), which has a maximum
allowed temperature of 450 °°C. It then flows to the
low temperature heat exchanger (1). Next, it flows
through the cooler (4), which is situated before the
entrance to the main circulator (3).

3. sc-CO2 power cycles chemistry
In contrast to other power cycles, such as steam and
helium, the data from the chemical composition of
the sc-CO2 medium, purification, and purity control
is rather scarce. Some knowledge can be drawn from
experience with nuclear reactors, which use carbon
dioxide (not in a supercritical state) as the primary
coolant. These reactors have been operated in Great
Britain (MAGNOX and Advanced Gas Cooled Reac-
tors) [15], and the first nuclear power plant in former
Czechoslovakia, which is A1, also used carbon dioxide
as a primary coolant [16].

3.1. Impurities in the CO2 medium
Impurities in the unit’s contents of volume percent-
age in the CO2 medium influence the thermodynamic
properties of the medium. For example, the power
consumption of the compressor when working with

a medium that is near the critical point increases by
six percent, whereas the medium purity decreases by
4.4 %. With a medium of 90.9 % purity, the compres-
sor power consumption increases by 34 % as compared
to 100 % with pure CO2. This increase in power
consumption is caused by a decrease in the medium
density, which is due to the impurities [17]. This phe-
nomenon is mainly significant for the systems with
a direct combustion. Examples of the medium compo-
sition in the direct combustion power cycles are listed
in Table 3.

Furthermore, the impurities cause the materials and
components to corrode and degrade, and they may be
the source of undesirable physicochemical processes
in the power cycle. The sources of the impurities are
as follows:

• Impurities in the source gas
• Residual air or gases present in the system prior to

the operation
• Corrosion and chemical reactions in the system
• Residual impurities on the component’s surfaces
• Lubricant leakage
• Penetration from the outside environment due to

the lack of tightness
• Desorption from the structural materials

Typical admixtures in the CO2 medium are as fol-
lows: O2, H2O, H2, CO, CH4, N2 [11, 18]. In the
direct combustion cycles that use synthesis gas as
a fuel, SO2, SO3, NO, NO2, and halogen compounds
may be present in the medium. Compounds of halo-
gens and sulphur usually cause and accelerate the
material’s degradation by corrosion. If the medium

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vol. 61 no. 4/2021 CO2 power cycle chemistry in the CV Řež . . .

Compound
Average value in
primary CO2 coolant

Limit value for
Average value
in supply gas

supply gas
(mg·kg−1)

H2O 700-1200 20 15
oil 1–5 5 1
H2 - 2 < 2
H2S, NH3 and others - 1 < 1

Table 4. The impurities in the primary CO2 coolant and supply gas in the A1 nuclear power plant [16].

does not contain these compounds, the corrosion is
influenced by the water and oxygen content.

When using compressors and other devices, oils
and other lubricants may be released into the circuit.
These compounds are soluble in sc-CO2. If the oil
content in sc-CO2 is higher than one percent by weight,
the oil coats the internal surfaces and negatively affects
the heat transfer properties [19].

As an example of CO2 medium composition, the
data for the CO2 primary coolant purity in the nuclear
power plant is listed in Table 4 [16].

3.2. Purification and purity control
methods

In some devices, oil separators are used. For example,
in the SCARLETT loop, the oil separator is located
after the compressor. The separator separates 99 % of
the oil that is contained in the medium in the loop [20].
To limit the damage to the turbines and other parts
of the devices, the particle separators are inserted
into the circuit. For lower flow rates, the “Y filters”
(Figure 2) can be used, through which the medium
passes.

Figure 2. The Y-filter [21, 22].

For higher flow rates, other types of particle filters
should be used, as shown in the experimental loop in
SunShot in SwRI [11].

Other gaseous impurities can be separated by ad-
sorption. The adsorption separation methods for
medium purification in the supercritical carbon diox-
ide experimental loop in Centrum výzkumu Řež s.r.o.
will be tested over the next few years. In ref. [23],
the primary CO2 purification method was based on
condensation and a subsequent vaporization. Part of
the gas flow was injected into the rectification column
to separate the fission products (Xe, Kr, I).

3.3. Methods of analytical purity
control

For the impurity content control, the analytical meth-
ods were based on gas chromatography (GC), gas
chromatography with mass spectrometry (GC-MS),
infrared spectroscopy, etc. The analytical system for
the supercritical carbon dioxide experimental loop
will also be developed over the next few years within
the special project. Currently, the combination of the
gas chromatography with the helium ionization detec-
tor (GC-HID) and the 1-channel moisture analyser
is based on changes to the infrared light wavelength.
The experience with these technologies was obtained
in connection with another technology: the high tem-
perature helium experimental loop. The details were
published in ref. [24]. The GC-HID method is sensi-
tive when determining the content of H2, CO, CH4,
O2, and N2 (the contents of a 10−5 volume percentage
can be detected). One disadvantage of this method is
that the HID detector requires helium as a carrier gas.
Helium must be added separately for the analysis, be-
cause the loop that the gas is based on, which is CO2,
will be sampled (in contrast to the helium loop), and
the chromatographic method should be adjusted to
these conditions. Additionally, the chromatographic
analysis is relatively slow, as it lasts approximately
20 minutes.

The probe of the moisture analysis will be placed
directly into the medium in the low-pressure part of
the loop. The maximum gas pressure outside of the
moisture analyser probe is 20 MPa. The data from
the moisture content in the sc-CO2 medium in the
loop will be measured continually.

3.4. Organic impurities measured during
the first long-term operation of
the supercritical carbon dioxide
experimental loop at CV Řež

During the first long-term (1,000 hours) operation
of the loop, the sampling of the CO2 medium in the
loop was carried out on the seventh, 15th, and 34th
day of operation. The purpose of the sampling was
to determine the amount of undesired minor organic
impurities in the medium in the loop. The loop was
operated at a temperature of 550 °C in the test sec-
tion and a pressure of 20 MPa in the high-pressure

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J. Berka, J. V. Ballek, L. Velebil et al. Acta Polytechnica

Figure 3. The sum of the organic compounds in the CO2 medium samples.

Figure 4. The relative distribution of organic compounds in the sample from the seventh loop operation day.

section. During the operation, an average of approx-
imately 40 kg of CO2 per day was drained from the
loop and replaced to remove possible impurities from
the medium in the loop.

The samples were taken by passing the gas through
the sampling tubes with the active carbon. The vol-
ume of the samples was 10-170 l, with a pressure of
100 kPa and a temperature of 25 °C. In the next step,
the compounds that were adsorbed by the active car-
bon were desorbed by carbon disulfide, which was
subsequently determined by the GC-MS technique.

The amount of the organic compounds in the loop’s
medium that were determined in the samples has
been recorded in the chart in Figure 3. The contents
of the organic impurities in the medium decreased
from ca. 1800 to 5 ng·l−1. In the sample from the
seventh day of operation, several organic compounds
contained a large amount of benzene. The relative
distribution of the organic compounds in the seventh

operation day sample is shown in Figure 4. In the
other samples, only benzene was detected. The source
of the organic compounds in the loop medium could
be the residual organics from the loop production,
such as lubricants, degreasers, and dissolvents. The
amount of organic impurities significantly decreased
during the loop operation, which is likely due to the
continuous replacement of CO2 in the loop.

4. Conclusion
The sc-CO2 power cycles are a perspective technology
due to the high efficiency of the mechanical to electric
power conversion, their compactness, etc. Centrum
výzkumu Řež s.r.o. (Czech Republic), along with sev-
eral other partners, has investigated this field. This
research institution also operates a semi-industrial
facility, which is the supercritical carbon dioxide ex-
perimental loop. The research aims to test materials
for sc-CO2 technologies, physical properties, and ther-

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vol. 61 no. 4/2021 CO2 power cycle chemistry in the CV Řež . . .

mohydraulic properties of the sc-CO2 medium as well
as the coolant chemistry and the related purification
& purity control methods.

As typical impurities in sc-CO2 cycles with indi-
rect heating, O2, H2O, H2, CO, CH4, N2 and, in
some cases, also organic compounds (oil, etc.) were
identified. As analytical methods suitable for CO2
purity control, Gas Chromatography with Helium Ion-
ization Detector (GC-HID) connected directly with
the sampling point of the circuit and optical hygrom-
eter with probe placed directly next to the sc-CO2
circuit were proposed. The methods will be tested.
For the determination of trace concentrations of or-
ganic compounds, the Gas Chromatography with Mass
Spectrometry detector (GC-MS) can be used. This
method was verified by an analysis of real samples
from a sc-CO2 loop operation. For the separation
of impurities from the CO2, the processes based on
adsorption will be tested within the continuation of
the research program.

Acknowledgements
The presented work was financially supported by the Min-
istry of Education, Youth and Sport Czech Republic -
project LQ1603 “Research for SUSEN”. This work has
been performed within the SUSEN Project and co-financed
within the framework of the European Regional Devel-
opment Fund (ERDF) in project CZ.1.05/2.1.00/03.0108,
and the European Structural and Investment Funds (ESIF)
in the project CZ.02.1.01/0.0/0.0/15_008/0000293). Some
results that have been presented in the article were
achieved within the project No. TK02030023 supported
by the Technology Agency of Czech Republic (TACR).

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	Acta Polytechnica 61(4):1–7, 2021
	1 Introduction
	2 R&D in sc-CO2 technologies
	3 sc-CO2 power cycles chemistry
	3.1 Impurities in the CO2 medium
	3.2 Purification and purity control methods
	3.3 Methods of analytical purity control
	3.4 Organic impurities measured during the first long-term operation of the supercritical carbon dioxide experimental loop at CV Řež

	4 Conclusion
	Acknowledgements
	References