Abstract:
Beatrix Gold Mine, a deep-level gold mine in the Free State province of
South Africa, has the highest methane emission rate of any gold mine in
the country. Methane is emitted from underground sources intersected
during mining operations and is liberated into the general mine
atmosphere. The total methane emission rate for the mine is of the order of
1 600 l/s and the South section of the mine emits approximately 1 000 l/s
of methane gas. The mine has a history of gas accumulations which have
led to a number of underground explosions. Following the last explosion in
2001 and the subsequent investigation, a number of recommendations
were made. Two of these were to consider extracting the underground
mine methane to render the mine atmosphere safe, and to declare
hazardous locations that require special operating procedures. A number
of such workplaces have now been declared at the South section of the
mine.
Methane gas is a potent, explosive greenhouse gas whose contribution
to global warming and climate change is 21 times higher than that of
carbon dioxide. To reduce its inherent danger and to mitigate its global
warming impact, a carbon credit project under the Clean Development
Mechanism (CDM) of the Kyoto Protocol has been developed and
implemented, the aim being to capture and destroy the methane at Beatrix
mine.
The mine has constructed an extraction system to capture and extract
400 l/s of the methane. Percentage methane (per volume) of the gas
intersected at source is 85%, with negligible concentrations of other
hydrocarbons and water associated. The mine contracted the services of
Group Five to design and construct the flare and ancillary equipment on
surface, and Promethium Carbon was contracted to assist with the carbonrelated
aspects, approval framework, and administration of the project.
A number of design and construction challenges had to be faced to
extract and transport the gas effectively to the surface of the mine as the
emitters are approximately 3 600 m away from the mine shaft at a depth
of 860 m. Further considerations were the requirements for the type of
column to be used to transport the methane gas, the pressure loss over the
system, the safety systems needed to address the risk factors involved in
the transport of the methane gas, and a suitable pumping system to
extract the gas to the surface. The system operates under negative
pressure provided by two blowers on surface delivering the emissions to a
flare capable of burning off 450 l/s of methane gas.
In this paper a number of benefits for the mine are discussed. These
include, but are not limited to, the removal of approximately 55% of the
total volume of methane gas from the general body of the air in the
geographical areas of the mine where the methane gas is emitted into the
atmosphere, and reducing the risk of methane-related incidents. A further
benefit of this project is the mitigation of the global warming impact of the
methane gas and the reduction of the mine’s carbon footprint by
approximately 25%. This project could also assist in alleviating the energy
shortage being experienced in South Africa by means of the planned
generation of 4 MW of electrical power, utilizing the methane gas, as a
second phase of the project.