Title: The viability of supplying an industrial park with thermal energy from Menengai geothermal field, Kenya

Author(s): Philip Jack M. Kiruja

Type:

University Thesis

Year of publication:

2017

Specialisation:

Geothermal Utilization

Publisher:

United Nations University, Geothermal Training Programme

Place of publication:

Reykjavik

Number of pages:

ISSBN:

ISBN 978-9979-6

Document URL: Link

Supervisors: Páll Jensson , Páll Valdimarsson

Keywords:

Geothermal, industrial park, energy, viability, Menengai

Abstract

Kenya has an installed geothermal capacity of more than 600 MWe, and more geothermal energy
projects are under development (Matek, 2016). One of the fields under development is Menengai,
which is owned by the Geothermal Development Company (GDC). Besides developing the Menengai field
for electricity generation, GDC intends to establish and industrial park which will be powered
using geothermal energy in the same field. The industries located in the park will not only benefit
from green electricity but they will also utilise the other by-products of electricity generation
such as excess heat in separated brine and/or low pressure wells, dissolved substances in the
geothermal brine, non-condensable gases such as carbon dioxide and hydrogen sulphide among other
by-products. Analysis of the demand for industrial process heat in the park resulted in the
creation of three scenarios with a demand of between 6 MWt and 22 MWt. This energy would be
obtained from hot geothermal brine produced in the Menengai field. Five possible options for
supplying this energy to the industries were analysed. The options considered for energy supply
were separated brine from power generation, brine from low pressure wells or a combination of both.
This energy would be extracted through heat exchangers and delivered to the industries through
pipes, a distance of 6 km. The energy was cascaded among different thermal processes in order to
achieve a high degree of energy utilisation. This resulted in a 60% reduction in the amount of
water required to transport thermal energy to the industrial park. Since water is the energy
carrying medium, a suitable tariff for the hot water was determined to have a floor of 2.39 $/m3
and a ceiling of 7 $/m3. The floor price was determined using the operating costs as the basis
while the ceiling price was determined using the price of alternative sources of fuel for
industrial applications. All the analysed scenarios and options proved to be profitable after 25
years of operation with a payback period of between 6 and10 years and an Internal Rate of Return of
between 20% and 30%. The most suitable option for supplying thermal energy to the industrial park
fo as then determined by
considering a number of criteria.

Documents and links

http://os.is/gogn/unu-gtp-report/UNU-GTP-2017-01.pdf