AP01_6.vp


1 List of symbols
CHP combined heating and power plant
GT gas turbine cycle
ST steam turbine
WHB waste heat boiler
C condenser
HE heat exchanger
HP heat pump
mFWH mass flow of secondary geothermal water used for

heating feed water
mDH mass flow of secondary geothermal water used for use

in the DHN
mSCGH mass flow of the secondary carrier of geothermal heat

2 Introduction
Revolutionary structural changes will be needed as world-

wide energy consumption increases with rising populations
and higher living standards. In response to the higher im-
pacts on the environment (especially the threat of climate
change caused by the greenhouse effect) and decreasing
reserves of fossil fuels, other sources will be needed. The
utilization of renewable sources is expected to increase above
all between 2010–2040. In this time period, the proportion of
power supplied from renewable sources will probably rise
from 5 % to approximately 35 %. Around 2050 the propor-
tion from non-renewable and renewable sources will be equal,
and after 2060 the proportion of power from renewable
sources will be about 40 %.

For Slovakia, which is extremely poor in fossil fuels, the
prospect of such an evolution should provide strong motiva-
tion for more intensive utilization of sustainable energy
sources, especially solar and geothermal energy. Their cur-
rent usage (6 % and 2 %) is much lower than it could be. While
solar energy is suitable for use in projects in the range of some
kW, due to its low concentration, the power output from geo-

thermal projects is significantly higher, and can be used for
major projects. The plan for the geothermal project in Košice
is to utilize about 100 MW heat output from 8 geothermal
doublets. About 2500 TJ of heat could be obtained in this way.
This is undoubtedly one of the boldest intitiatives of its type
in the world today.

3 Feasibility of utilizing geothermal
heat directly in the district heating
network (DHN)
The simple, direct use of geothermal heat in the District

Heating Network (DHN) cannot be a feasible way of replacing
the existing CHP plant under the current economic
circumstances, due to its low efficiency. The main reason for
this low efficiency is the conflict between geothermal heat and heat
produced in cogeneration, which means that the heat produced
by the cogeneration unit would be replaced by geothermal
heat. Limiting the cogenerated heat production would cause
a decrease in power production, which plays a key role in the
efficiency of this unit. Therefore this alternative must be
rejected.

The energy policy of the government, which supports the
utilization of renewable sources, accepts the plan to establish
of a cogeneration unit in 2004–2005 to replace a part of
the CHP plant that is reaching the end of its working life.
Cogeneration based on a gas-steam cycle is one of the most ef-
ficient ways of converting fossil fuels to other profitable
energy forms, and for this reason it is one of the priorities in
the energy policy. Its efficiency is based on longest possible
utilization in the course of a year, as in the case of geother-
mal energy. Due to low demand for heating in the summer
period, it is impossible to fulfil this condition.

The way to improve the efficiency of the geothermal pro-
ject in Košice is by changing the basic philosophy. It is also
important to reduce investment costs and to decrease the
amount of geothermal heat used in a year.

14 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 41  No. 6/2001

A Geothermal Energy Supported
Gas-steam Cogeneration Unit as
a Possible Replacement for the Old Part
of a Municipal CHP Plant (TEKO)
L. Böszörményi, G. Böszörményi

The need for more intensive utilization of local renewable energy sources is indisputable. Under the current economic circumstances their
competitiveness in comparison with fossil fuels is rather low, if we do not take into account environmental considerations. Integrating
geothermal sources into combined heat and power production in a municipal CHP plant would be an excellent solution to this problem. This
concept could lead to an innovative type of power plant – a gas-steam cycle based, geothermal energy supported cogeneration unit.

Keywords: geothermal energy, combined heat and power plant, heat pump, waste heat boiler, district heating network



4 Integrating the geothermal potential
of the Košice basin into the
combined heat and power
production system in TEKO

Motivated by a vision of supplying energy for Košice
with a major proportion of clean and renewable energy,
which could qualify for membership of the prestigeous
“Energie-Cités – Association of European Municipalities for
a Local Sustainable Energy Policy” network, the authors of
this paper sought for a feasible concept, in which geothermal
energy would be utilized in a system of combined heat and
power production, rather than only direct utilization in the
DHN. The combined heat and power production would not
be limited but would be supported by geothermal heat. This
solution would be advantageous for the two companies TEKO
and GEOTERM, and also for the end users.

The initial results were published in a summarized form.
The aim of these publications was to draw the attention of
engineers and above of business people to the fact that the
low efficiency of only direct utilization of geothermal energy
in the DHN will not be compensated for by the increasing
price of fossil fuels. Approximately 60 % of the cost of geo-
thermal heat is accounted for by energy costs, and the increas-
ing cost of fossil fuels would influence all its components,
so the desired effect would not be achieved. Moreover, the
current rising price of electricity increases the advantages
of cogeneration, but reduces the advantages of geothermal
heating. For this reason, the use of hybrid CHP plants with

the simultaneous use of fossil and geothermal sources was
considered. This can be done using existing machinery, but
a special design for the planned gas-steam cycle seems to be
desirable. A gas-steam cycle based cogeneration unit with
integrated support of geothermal energy could be imple-
mented to supply the city with heat.

5 The concept of a gas-steam
cogeneration unit supported by
geothermal energy
There are many possible technical solutions of the gas-

-steam cogeneration source with integrated support of
geothermal energy. In this concept geothermal heat is used
mainly for heating the feed water in the steam cycle, so
condensation production of electricity should be dominant in
each proposal. The highest energy efficiency and the lowest
environmental pollution can be achieved by the concept illus-
trated schematically in Fig. 1.

In this proposal the stream of secondary geothermal water
�mSCGH will be divided into two parts in TEKO:
� �mhfw for heating the feed water (condensate) in the heat

exchanger of the steam cycle,
� �mDH for direct utilization in DHN.

Because geothermal heat is more efficient for heating the
feed water, the flow �mhfw should be higher than �mDH. After
mixing the returning flows that were cooled down to different
degrees, the heat will be pumped from the resulting flow,
using the heat pump HP for indirect utilization in DHN. The

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Acta Polytechnica Vol. 41  No. 6/2001

Fig. 1: Principal technological scheme of the gas-steam cogeneration unit with geothermal support



heating water in the cycle of the heat pump’s condenser can
be overheated as required in the waste heat boiler WHB. In
the evaporator of the heat pump the secondary geothermal
water can be cooled down to such an extent that it can be
used for cooling the condenser C of steam turbine ST. In
condenser C the secondary geothermal water will be heated
by 8 to10 K by a part of the heat loss. Finally, in the waste heat
boiler the secondary geothermal water can be heated by
the heat losses from the outgoing flue gases at the same tem-
perature, as is assumed in the case of only direct utilization in
DHN. The flue gases can be cooled down in this way below
the dew temperature and in addition to the sensible heat also
the latent heat of the flue gases can branch away. After this,
not only the pollution load but also the load by emission from
exhaust emissions will be reduced, because the moisture will
clean the outgoing flue gases. The heat losses of the waste
heat boiler and condenser, which constitute a substantial part
of the heat losses, will be accumulated through the geother-
mal water being reinjected into the earth’s crust.

The parameters of the steam cycle will be adjusted to the
processes analyzed above. The electric power of the steam
turbine will also be determined mainly by the amount of con-
densate, and also indirectly by the stream of the secondary
geothermal water used for heating the feed water. Taking into
account the anticipated abundance of geothermal doublets,
such a stream is expected, so at least two pressure levels of
superheated steam must be dealt with.

There are other possible ways of designing the gas tur-
bine, depending on the degree of overheating. In the extreme
case of a gas-steam cycle without overheating, which is the
most efficient variant, the power output of the gas cycle will be
unnecessarily high, considering the current aims for the utili-
zation of geothermal heat. For this reason it is important to
turn our attention to overheating. The degree of overheating
should be adjusted to the selected gas turbine. The ideal
power output is when no additional air for combustion will
need to be overheated.

It is important to pay attention to the concept of the waste
heat boiler, which will be different from the standard dou-
ble-pressure design, with (probably) high degree of overheat-
ing by the last heat exchanger, where the flue gases will be
cooled to below dew point. The exiting of the flue gases into
the atmosphere must also be adjusted to it.

The heat pump integrated into the combined heat and
power production system, which pumps the heat from the
returning secondary geothermal water into the CHP, plays
a key role. If the parameters of the heat pump are chosen
properly, its application will be effective, because the heating
and cooling output would be used all year round. These
parameters should therefore be chosen in such a way that the
heat pump can supply the whole city with heat for domestic
warm water production.

6 Simplified analysis of winter period
operation of a geothermal energy
supported gas-steam cycle based
cogeneration unit
As shown in the scheme in Fig. 1., the operation of the

gas-steam cycle based cogeneration source was analyzed to

compare the effects of the possible ways of utilizing geother-
mal energy with the original, still officially supported idea,
which involves direct feeding into DHN. The main parame-
ters of the analysis were the following:
� Geothermal heat is distributed by secondary water to the

TEKO from 6 doublets. If one doublet produces 60 kg/s of
mains water and the streams on the primary and secondary
side of the heat exchangers of transmission line are equal,
there is a total of 360 kg/s of secondary geothermal water.
The input temperature into the TEKO is approximately
120°C.

� The stream of secondary mains water is divided in the ratio
2:1. This means that in the case of year-round operation
240kg/s water will be used for heating the feed water (from
4 doublets) and 120 kg/s of water will be directly used in the
DHN.

� Parameters of the high pressure steam
pressure: 10 MPa
temperature: 500°C
stream: 160 kg/s

� Parameters of the low pressure steam
pressure: 0,5 MPa
temperature: 300°C
stream: 80 kg/s

� Condensation pressure 0.004 MPa
� Parameters of the primary water in the DHN

120°C/50°C
� Heat output of the heat pump 45 MW
� Temperature of the secondary water at the output of the

TEKO 60°C

These parameters indicate that it would be possible to
obtain about 245 MW electric power from the steam cycle and
the total heat output of the source would be from 190 to
200 MW. The total electric power of the source would depend
on the selected gas turbine and on the degree of overheating,
which is relatively independent from the utilization of geo-
thermal heat. It is in principle possible to imagine a variant
in which the cycle of the steam turbine would operate in the
interval of the basic load and the gas cycle would be used as
a source for regulation of electric power.

This source would provide GEOTERM with 2500 TJ/year
from 6 doublets instead of 8, which means a saving on invest-
ment costs of about 14 mil. USD, and also lower distribution
costs. These savings could be invested in TEKO. This vari-
ant seems more advantageous for TEKO, which would pay
for about 2500 TJ/year but would in fact be able to utilize
4000TJ/year as heat (this difference represents the heat losses
leaving the condenser of the steam cycle and the waste heat
boiler) and more than 1000 TJ/year as cooling capacity. More-
over, the company would decrease its emissions, and reduce
its impact on the environment. World Bank studies have

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Acta Polytechnica Vol. 41  No. 6/2001

Type of emission Environmental profit USD/t

CO2 48

NOx 1100

SOx 2200

Table 1: Savings on investments by decreasing emissions



shown that the following savings can result from decreasing
emissions and reducing environmental damage.

Taking these savings into account, it would even be advan-
tageous for TEKO to buy the geothermal heat at a price
higher than its selling price.

7 Conclusions
The concept of a geothermal energy supported gas-steam

cycle based cogeneration unit appears very promising and
our analysis shows that a new philosophy may lead to good
results. The specification of the optimal variant of this con-
cept and also the overall evaluation of its power supply,
economic and environmental potential should form the sub-
ject of a very serious feasibility study.

The establishment and functioning of such a unique work
would provide more power with fewer environmental im-
pacts, contributing to the development of an efficient tech-
nology for converting fossil fuels to other energy forms,
together with the use of geothermal sources. Optimized
integration of the secondary geothermal heat carrier into the
system of combined heat and power production in a gas-
-steam cycle based cogeneration unit and into the DHN could
lead to very intensive utilization of its enthalpy, and also to
a reduction in the consumption of primary energy. At the
same time, huge heat losses or an accumulation of them in the
earth’s crust will be utilized, and the working life of the geo-
thermal wells will be extended.

The realization of this project would be a success for the
energy policy of Slovakia.

The main aim of the energy policy of the European Union
is to increase the proportion of renewable energy source utili-
zation from 6 % to 12 % in 2010, and to reduce the emissions
of greenhouse gases by 8 % in comparison with 1990. Slovakia
has serious ambitions to join the EU, and will have to partici-
pate in this programme. If any version of the geothermal
project is realized, it will form a major part of Slovakia’s
renewable clean energy programme. The interest of Slovak
engineers in the new concept is surprisingly low, paradoxi-
cally lower than that of engineers in foreign countries. There
has been no adequate response from the state authorities
dealing with regional energy and environmental policy was
presented. As a result of this neglect, no local funding has yet
been made available for this work.

References
[1] Böszörményi, L.: Možnosti zlepšenia ekonomických ukaza-

te� ov košického geotermálneho projektu. Konferencia s med-
zinárodnou účas�ou „Podnikanie v energetike“. DT
ZSVTS Košice, Košice 1998.

[2] Böszörményi, L.: Úvahy o využívaní hydrogeotermálneho
potenciálu Košickej kotliny pri kombinovanej výrobe tepla
a elektriny. Časopis EE, 5, 1999, č. 6

[3] Böszörményi, L.: Geotermálna podpora kombinovanej výroby
elektriny a tepla. Seminár Kogeneračné zdroje, DT ZSVTS
Bratislava, Bratislava, 2000

[4] Böszörményi, L.: Optimierte Geothermienutzung bei der ge-
koppelten Strom- und Wärmeerzeugung in einer GuD-Anlage.
International Conference World Sustainable Energy
Day 2000, Wels/Austria, 2000

[5] Böszörményi, L.: Kraft-Wärme-Kälte-Kopplung mit geo-
thermischer Unterstützung. VDI-Berichte 1594, VDI Verlag
GmbH, Düsseldorf, 2001

[6] Geotermálna energia pre centrálne zásobovanie teplom v meste
Košice. GEOTERM Košice, Košice, 1999

[7] Riešenie náhrady zastaralých zdrojov tepla v TEKO Košice.
Výskumný ústav energetický EGÚ Bratislava, Bratislava,
1996

[8] VDI Nachrichten Magazin. Sonderbeilage zur EXPO
2000, VDI Verlag GmbH, Düsseldorf, 2000

Doc. Ing. Ladislav Böszörményi, CSc.
phone: 00421-95-6024241
fax.: 00421-95-6321558
e-mail: boszla@ccsun.tuke.sk

Department of Building Structures
Technical University of Košice
Faculty of Civil Engineering
Vysokoškolská 4, 042 01 Košice, Slovak Republic

Ing. Gabriel Böszörményi
e-mail: G.Boszormenyi@sh.cvut.cz

Department of Fluid Dynamics and Power Engineering-
Division of Compressors, Refrigeration
and Hydraulic Machines
Czech Technical University in Prague
Faculty of Mechanical Engineering
Technická 4, 166 07 Praha 6, Czech Republic

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Acta Polytechnica Vol. 41  No. 6/2001