Download: PDF- Riskless separation of particles out of big water flows in the deep geothermal energy


Riskless separation of particles out of big water flows in the deep
geothermal energy

Ulrich Pfeffer, Darina Leinhos
Pfeffer Filtertechnik

Keywords: deep geothermal energy, scaling, solid-/liquid separation, particle elimination, high
temperature, high pressure, riskless, safe, automated purging system, neutralizing agent, cooling


Geothermal waters from deep drilling usually contain large quantities of unwanted particles with
different characteristics. Under conditions of changing pressure and temperature it turns into mineral
scaling which blocks the heat exchangers and piping continuously. As a result, the geothermal
utilization is strongly impaired. To overcome these operational difficulties an efficient particle
elimination system is highly-desired. Cyclonic separation with an automated purging unit offers an
innovative technology for particle removal in a reliable and risk free way for the operator. Particles
are separated out of the water stream via centrifugal forces and subsequently removed via
automated purging unit to a final storage vessel without any interruption of a water flow or human
intervention. Dosing of a neutralizing agent and cooling of a sludge in the purging unit ensures the
risk free extraction of particles even under conditions with high temperature and pressure and high
concentrations of dissolved gases or aggressive compounds.

1. Introduction

Geothermal energy is heat derived within the sub-surface of the earth. Water and/or steam carry the
geothermal energy to the earth’s surface. Depending on its characteristics, the geothermal energy
can be used for heating and cooling purposes or to generate clean electricity (IRENA, 2017).
Thanks to geothermal utilization the increasing demand for renewable energy could be lowered.
However, its full exploitation is still limited by many technical problems which are to be overcome.

The composition of geothermal water from deep drillings is characterized by the macroelements of
the reservoir rock and the subsurface environment to which is exposed most of the time. The most
frequently observed elements with high concentrations are
Na+, K+, Ca2+, Mg2+, HCO3-, CO32-, SO42-
and CO2. Other micropollutants are heavy metals such as mercury, copper, lead, zinc, silver, iron,
zinc, arsenic, manganese, cadmium, uranium, cobalt (GUDE, 2018). Due to changes in temperature
and pressure the different equilibria of dissolved gases and solid forms of the components can be
shifted towards the formation of mineral precipitations (scaling). Decreased degree of heat transfer
in heat exchangers due to clogging, significantly reduced inner diameter of piping, leaking valves or
even blocking of the pores of a swallow hole are among the most significant results of these
interactions. Therefore, an efficient removal of sand particles, scaling or freshly formed suspended
microparticles out of the system using a reliable and risk free way for the operator is inevitable. High
degree of salinity, high temperatures and pressures along with large quantities of dissolved gases in
water make this a real challenge.

Particle elimination through the application of common backflushing filter systems is not adviseable.
The filter screens are often coated with hard mineral coatings and eventually blocked so that
automatic backflushing is not possible anymore. Furthermore, high pressure and high temperature
bring automatic backflushing filters to their technical limits. Therefore, only barrier filter units with the

possibility of a manual cleaning conducted by the operator can be applied. Unfortunately, the direct
contact of the operator with the hard coatings from the filter during the manual backwashing can be
dangerous. In many cases the separated particles contain toxic heavy metals or radioactive
substances e.g. mercury or arsenic which come along with significant health risks for the operator
besides potential hazards caused by temperature, pressure and dissolved gases.

2. Cyclonic separation with automated purging unit

The newly developed and here presented, patented system of cyclonic separation using centrifugal
force with connected automated purging unit faces all these difficulties in a unique way not
previously reached.

2.1 Cyclonic separation

The cyclonic system removes particles with sizes above 75 micron and a density of above 2.6 from
the fluid up to an efficiency of 99 %. Smaller or lighter particles are also eliminated to a decreasing
percentage according to their size and density. For separation of a very fine particles double or triple
cyclonic separators can be applied. The separation works reliably due to centrifugal forces even
with very large flows of water of 1000 m³ and more. As there are no moving parts, changes in
temperature and pressure do not pose a problem to the system. Furthermore, there is no filter
element to get coated and blocked by mineral coatings and coarse particles.

Water enters the separator tangentially on the side so that it forms a rotary motion. Due to the
cross-section reduction between the upper chamber and the separation barrel, the rotational speed
of water is accelerated as far as an effective separation proceeds up to the necessary efficiency via
a centrifugal force. The medium flows down the separation barrel, whereas the contained particles
are pushed outside to the barrel wall. The separator is constructed in a cylindrical form to minimize
the wearing via an abrasion by particles. On the lower end of the separator, there is a solids
collection chamber, which is partly separated from the separation barrel by a deflecting plate. The
particles are expelled via a rotary motion through a slot between the separation barrel wall and the
deflecting plate from the water stream into the collection chamber. The largely particle-free water
stream flows via the pressure gradient to the center of the water swirl and is deflected upwards and
leaves the separator through the discharge pipe on the upper chamber.

The solids collection chamber is periodically opened to the atmosphere via a valve either manually
or automatic (using a timer) in order to sweep the separated particles away. The differential
pressure between the system and the atmosphere washes the particle sludge out via a sludge pipe
out of the system to waste (e.g. sedimentation tank). By this simple process using system pressure,
the sludge extraction takes place without any additional motors, pumps, sensors or other unsafe
components. The purge valve is the only moving part in the system. In the event of failure of the
sludge automatic system, there is no interruption of the supply to the downstream systems. Only the
sludge pipe can get clogged and the particles in the main flow will just pass through the separator
not interrupting the process. In this case there is no clarification of the media. The blow-down takes
place during the normal operation and the operation occurs without any interruption.

In contrast to the barrier filter systems (e.g. mesh and sand filters), which are manifesting a rising
differential pressure with an increasing extent of clogging, the separator is always characterized by
a static pressure loss during the operation. The pressure loss (the differential pressure) depends
only on the flow rate and rises relatively to the flow rate almost linear up to a maximum of 0.8 bar.

The abrasion is negligible small and the assumed maintenance free life expectancy of the device
accounts for at least 5 years. Thanks to the special concept and the high-performance reliability it is
not necessary to design the system as a redundant system.

2.2 Purging system

Separated solid particles are stored temporarily in a purging system consisting of several chambers
isolated from each other by automatic valves. Particle treatment is conducted according to a
patented procedure. The subsequent risk free extraction out of the system occurs automatically
without any interruption of the water flow. The Fig. 1 depicts the cyclonic separator with an
automated purging unit for the applications in deep geothermal energy.

Fig. 1 : Cyclonic separator with associated automatic purging unit for deep geothermal energy.

The purging unit comprises a purging chamber downstream the separator sludge outlet, in which
separated particles are temporarily stored before being extracted securely. The chamber is isolated
by two automatic valves, the upper valve between the sludge outlet and the purging chamber is
open so that the particles fall into the chamber by gravity, the lower valve is closed. After the
purging chamber has been filled and the level sensor has been activated, the upper valve would
close and the lower valve would open in order to empty the chamber.

Adjacent to the purging chamber there is a dosing chamber for injection of a neutralizing agent in
order to neutralize the dissolved gases or chemical and physical reactive compounds in the
pressurized fluids and to avoid their abrupt evaporation under atmospheric pressure. As a
neutralizing agent an alkaline or acidic solution can be applied. In this way for instance CO2 can be
converted after adding an alkaline solution to sodium bicarbonate (HCO3-), which can be extracted
without any risk out of the system. The adjustable valve between the purging chamber and dosing
chamber allows unpressurized introduction of the neutralizing agent into the dosing chamber. By
connecting the purging chamber with the dosing chamber, a sufficient mixing for the appropriate
chemical reaction is ensured. Furthermore, both chambers are covered with a cooling jacket for fluid
cooling below its boiling point e.g. 100°C for water so that the temperature of reaction of gases or
particles with a neutralizing agent is supervised and a water evaporation is prevented. Cooling water
or cooling air can be used as a cooling agent. After the neutralization process has been completed a
safe extraction of particles can be conducted.

The complete system is designed for fully automatic operation at the highest safety level for the
operator and environment under the most difficult operating conditions. Even pressures up to 40
bar, temperatures above 200°C and high quantities of dissolved and aggressive compounds and
gases in concentrations typical for deep geothermal energy can be handled.
This concept in a simpler version is certainly suitable for separation of particles out of groundwater
close to the surface area, in heating and cooling district networks and in cooling towers for the
cooling water treatment.

3. Outcome

Cyclonic separation offers an effective method for a particle elimination in water streams. An
automatic purging unit installed on the purge outlet of the separator allows a safe extraction of the
particles even under conditions of high temperature and pressure along with high concentrations of
dissolved gases or aggressive compounds. Therefore, its application in deep geothermal energy is
appropriate for scaling prevention. The simplicity and safeness of the total system is guaranteed by
the highest technical and safety standards used in the manufacturing of the systems.

IRENA: Geothermal Power: Technology Brief, International Renewable Energy Agency, Abu Dhabi (2017)
GUDE, G.G.: Geothermal Source for Water Desalination – Challenges and Opportunities, Renewable Energy
Powered Desalination Handbook (2018)

Pfeffer Filtertechnik, Grosse Gasse 10, 73333 Gingen, Germany
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