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Efectos de la represa Casa de Piedra en la variación témporo espacial de las características hidrológicas y del diseño de drenaje del Río ColoradoCazenave, Héctor Walter 12 December 2011 (has links)
El río Colorado se ubica en la parte Norte de la Patagonia argentina y atraviesa con dirección Oestenoroeste - Sur-sureste un sector del país de condición árida y semiárida ubicado entre la Cordillera de los Andes y el océano Atlántico, con un recorrido cercano a los 1.000 km. Esta tesis doctoral aborda el estudio de las características hidrológicas y el estudio específico de las variaciones en el diseño de drenaje de un tramo testigo ubicado en un área predeterminada por su cartografía secuencial y fiable en relación con las posibles variaciones hidrogeomorfológicas. Dentro de la problemática general que presenta el río Colorado, se tuvo en cuenta la función del río Curacó, último tramo de la gran cuenca Desa-guadero Salado Chadileuvú, a la que le da carácter de exorreica. Las periódicas activaciones del Curacó crean serios problemas de salinidad en las cuencas media y baja del Colora-do, parcialmente mitigados en la actualidad por la represa Casa de Piedra. El levantamiento del dique Casa de Piedra, sobre la parte final del alto valle, alteró drásticamente el comportamiento del río en cuanto al arrastre de sólidos. Por acción de su gran embalse se produce la deposición del mate-rial trasportado en suspensión, dándole una nueva condición física -y en parte también química- a las aguas emergentes del dique, que han dejado en el lago las arcillas y el limo que trasportaban. Esos materiales, antes de existir el dique, se depositaban aguas abajo e impermeabilizaban naturalmente los canales en las áreas de regadío de los valles medio e infe-rior. El agua que vierte Casa de Piedra, casi carente de sedi-mento, tiene una capacidad erosiva mayor que la que fluye antes del embalse; esa condición permite reducir el tiempo de formación de meandros con respecto a sectores de aguas arriba de la presa. Esas condiciones han generado también el fenómeno conocido como aguas claras. El estudio ordena en el tiempo y el espacio las variaciones de curvas y meandros del tramo testigo, cuantificándolas. Aunque también se han visto alteradas las curvas de caudal y salinidad es en el gasto sólido donde el dique Casa de Piedra ha provocado los cambios más visibles y fundamentales en el ser y quehacer del río. La curva resultante de los nuevos valores refleja la situa-ción con respecto a la anterior y marca una fuerte disminu-ción en el acarreo. Esta tesis es además un aporte a poste-riores investigaciones interdisciplinarias, especialmente en el campo de la hidráulica y la geomorfología fluvial, dos disci-plinas bajo las cuales el río Colorado ofrece un amplio campo de estudios. El trabajo detecta, determina y cuantifica los cambios físicos y humanos generados por la presencia del dique, algunos ya evidentes y otros en trance de serlo. / The construction of Casa de Piedra dam, in the final stretch of Colorado river high valley, radically modified down waters the hydrologic river course, specially as regards sediment transport, the majority of which settles in the lake. Conse-quently, waters the dam distributes, contain a remarkable erosive capacity, and accelerate down waters hydrographic processes, increasing river meandering and bringing about what is known as the clear waters phenomenon causing adverse effects on watering zones. With the purpose of checking the fact in a quantitative way, cartographies from a certain stretch were taken, being this stretch considered a witness one in periods around 25 years, assessing meanders appearance and disappearance, and comparing these quantities with the variation -in the same sense-, that took place since Casa de Piedra start up. The quantities were sig-nificant considering the relatively short time gone by. The fact was checked in a new aero - photographic flight, according to which, in a shorter lapse, meanders number increased again in the witness stretch.
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Automated control of mine dewatering pumps / Tinus SmithSmith, Tinus January 2014 (has links)
Deep gold mines use a vast amount of water for various purposes. After use, the water is pumped back to the surface. This process is energy intensive. The control is traditionally done with manual interventions. The purpose of this study is to investigate the effects of automated control on mine dewatering pumps.
Automating mine dewatering pumps may hold a great number of benefits for the client. The benefits include electricity cost savings through load shifting, as well as preventative maintenance and pump protection procedures. By automating pumps, the client will benefit from operating more cost effectively and realising electricity cost savings. The equipment needed for pump automation and the procedures involved in the process are discussed as part of this study.
A DSM project was implemented in the form of a pump automation project. All safety and quality procedures were followed and training was provided where needed to ensure that personnel understand their duties and responsibilities. This ensures the sustainability of the project after completion.
The performance of the project was tested in manual mode, manual scheduled control, manual scheduled surface control and auto control. Manual intervention achieved the highest electricity cost saving of R8.25 million (11.4 MW load shift saving). To achieve this saving the system was exhausted to a point where columns and infrastructure started failing. Auto intervention achieved an electricity cost saving of R5.57 million (7.7 MW load shift savings).
The auto intervention achieved a lower electricity cost savings compared to the manual intervention. However, taking all factors into account, such as the damage to infrastructure after a period of manual control, the auto intervention proved the best balance for controlling mine dewatering pumps to achieve savings on the cost of electricity and system sustainability for optimal control. Automated systems can avoid system overload and protect the infrastructure from exhaustion. / MIng (Mechanical Engineering), North-West University, Potchefstroom Campus, 2015
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Automated control of mine dewatering pumps / Tinus SmithSmith, Tinus January 2014 (has links)
Deep gold mines use a vast amount of water for various purposes. After use, the water is pumped back to the surface. This process is energy intensive. The control is traditionally done with manual interventions. The purpose of this study is to investigate the effects of automated control on mine dewatering pumps.
Automating mine dewatering pumps may hold a great number of benefits for the client. The benefits include electricity cost savings through load shifting, as well as preventative maintenance and pump protection procedures. By automating pumps, the client will benefit from operating more cost effectively and realising electricity cost savings. The equipment needed for pump automation and the procedures involved in the process are discussed as part of this study.
A DSM project was implemented in the form of a pump automation project. All safety and quality procedures were followed and training was provided where needed to ensure that personnel understand their duties and responsibilities. This ensures the sustainability of the project after completion.
The performance of the project was tested in manual mode, manual scheduled control, manual scheduled surface control and auto control. Manual intervention achieved the highest electricity cost saving of R8.25 million (11.4 MW load shift saving). To achieve this saving the system was exhausted to a point where columns and infrastructure started failing. Auto intervention achieved an electricity cost saving of R5.57 million (7.7 MW load shift savings).
The auto intervention achieved a lower electricity cost savings compared to the manual intervention. However, taking all factors into account, such as the damage to infrastructure after a period of manual control, the auto intervention proved the best balance for controlling mine dewatering pumps to achieve savings on the cost of electricity and system sustainability for optimal control. Automated systems can avoid system overload and protect the infrastructure from exhaustion. / MIng (Mechanical Engineering), North-West University, Potchefstroom Campus, 2015
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A new approach to ensure successful implementation and sustainable DSM in RSA mines / Daniël Francois le RouxLe Roux, Daniël Francois January 2005 (has links)
In this study a new tool was developed that made new approaches possible for the successful
implementation of Demand Side Management (DSM) projects. The new approaches are
incorporated into a generic tool that makes it possible for Energy Services Companies (ESCos) to undertake DSM projects that were previously not possible with currently available technology.
Through these new approaches, maximum results can be obtained on a sustainable basis on the
clear water pumping systems of South African mines.
The author was responsible and participated in four different investigations and implementations of
DSM projects. These were grouped into three case studies. Each of these studies required different
new innovations.
The innovations described in this thesis include the adaptation of the Real-time Energy
Management System (REMS) that was developed and marketed by HVAC International, to mines
with intricate pumping systems, mines without any instrumentation and control infrastructure, as
well as to mines that make use of a Three Pipe Water Pumping System.
The tool developed and applied in these projects was part of Eskom's DSM programme. In this
programme, large electricity clients who wish to shift electrical load out of peak periods, are
assisted by having the total costs of such projects funded by Eskom. The fact that the clients will
most likely enjoy substantial electricity cost savings, (by not having to pay the high peak prices), is
a major attraction of this programme. Nevertheless, the programme is not moving as fast as it
should.
The National Energy Regulator (NER) has set an annual target of 153 MW load to be shifted since
2003. By the end of 2005, the accumulated target load to be shifted will be 459 MW. However,
Eskom has indicated that an accumulated total of only 181 MW load will have been shifted by the
end of 2005. This means that the Eskom DSM programme has actually only achieved 39% of its
target.
The innovations described in this thesis will help ESCos to address this shortfall more effectively / Thesis (Ph.D. (Mechanical Engineering))--North-West University, Potchefstroom Campus, 2006
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A new approach to ensure successful implementation and sustainable DSM in RSA mines / D.F. le RouxLe Roux, Daniël Francois January 2005 (has links)
Thesis (Ph.D. (Mechanical Engineering))--North-West University, Potchefstroom Campus, 2006.
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Researching the long-term impact of load management projects on South African mines / N.C.J.M. de KockDe Kock, Nicolaas Cornelius Jacobus Marthinus January 2006 (has links)
Thesis (M.Ing. (Electrical Engineering))--North-West University, Potchefstroom Campus, 2007.
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A new approach to ensure successful implementation and sustainable DSM in RSA mines / Daniël Francois le RouxLe Roux, Daniël Francois January 2005 (has links)
In this study a new tool was developed that made new approaches possible for the successful
implementation of Demand Side Management (DSM) projects. The new approaches are
incorporated into a generic tool that makes it possible for Energy Services Companies (ESCos) to undertake DSM projects that were previously not possible with currently available technology.
Through these new approaches, maximum results can be obtained on a sustainable basis on the
clear water pumping systems of South African mines.
The author was responsible and participated in four different investigations and implementations of
DSM projects. These were grouped into three case studies. Each of these studies required different
new innovations.
The innovations described in this thesis include the adaptation of the Real-time Energy
Management System (REMS) that was developed and marketed by HVAC International, to mines
with intricate pumping systems, mines without any instrumentation and control infrastructure, as
well as to mines that make use of a Three Pipe Water Pumping System.
The tool developed and applied in these projects was part of Eskom's DSM programme. In this
programme, large electricity clients who wish to shift electrical load out of peak periods, are
assisted by having the total costs of such projects funded by Eskom. The fact that the clients will
most likely enjoy substantial electricity cost savings, (by not having to pay the high peak prices), is
a major attraction of this programme. Nevertheless, the programme is not moving as fast as it
should.
The National Energy Regulator (NER) has set an annual target of 153 MW load to be shifted since
2003. By the end of 2005, the accumulated target load to be shifted will be 459 MW. However,
Eskom has indicated that an accumulated total of only 181 MW load will have been shifted by the
end of 2005. This means that the Eskom DSM programme has actually only achieved 39% of its
target.
The innovations described in this thesis will help ESCos to address this shortfall more effectively / Thesis (Ph.D. (Mechanical Engineering))--North-West University, Potchefstroom Campus, 2006
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Researching the long-term impact of load management projects on South African mines / Nicolaas Cornelius Jacobus Marthinus de KockDe Kock, Nicolaas Cornelius Jacobus Marthinus January 2006 (has links)
Eskom is currently facing an energy crisis due to the limited operational electricity generating
capacity in South Africa. The historically low electricity price, the rapid growth in economy
and the energy intensive nature of South African industries are the most common reasons for
the peak supply problem.
Various supply and demand technologies have been identified to address this energy crisis.
Due to the lengthy process of building new peaking load power stations, Eskom has initiated
the Demand-side Management (DSM) programme as a solution to the short-term supply
problem.
The National Energy Regulator (NER) has set targets to Eskom DSM to reduce the evening
peak demand by 153 MW per annum and 4 255 MW over a 20-year planning horizon. Due to
the energy intensive nature of the mining industry, it has been targeted for DSM savings. To
date there have been a number of DSM projects implemented on the clear-water pumping
systems of various mines, with a large potential for DSM savings identified on future projects
still unrealised.
The generation benefit of DSM load-shifting projects is twofold; firstly Eskom's evening load
capacity increases due to the reduction in demand during these periods and secondly, the
mine receives electricity cost savings due to load management practices. Because Eskom
DSM is dependent on the client consumer to accept and roll-out the DSM programme, client
satisfaction is of paramount importance. Due to the fact that load-shifting efforts require from
the mine to change their normal operating schedules, there is uncertainty on the impact and
knock-on effects of DSM projects on a mine.
Therefore, the purpose of this study is to investigate and thereafter quantify the overall
impact of DSM load-shifting on the clear-water pumping system of South African mines. A
generic model was developed by performing case studies on existing DSM projects. This
model was then applied to future DSM projects to validate the findings made throughout the
research study.
The case studies performed on existing DSM projects, as well as the results obtained when
modelling the overall impact of DSM on future mines, proofs that DSM definitely benefits a
mine. The total annual cost saving on the four future DSM projects is predicted to be in the
order of R 7.64 million instead of the R 4.27 million when considering only the electricity cost
savings to the mine. / Thesis (M.Ing. (Electrical Engineering))--North-West University, Potchefstroom Campus, 2007.
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Comparison between automated and manual DSM pumping projects / R.P. RichterRichter, Rudolph Petrus January 2008 (has links)
The purpose of this dissertation is to identify the best alternative method of load shifting on clear water pumping systems in the mining industry. This can be done through a comparison analysis between manual and automated Demand Side Management (DSM) projects. The study holds benefits for Eskom and any client wishing to participate in the program. Eskom, by choosing the best method, will ensure sustainable load shifting while the client benefits financially through lower electricity costs.
In order to perform this study, research was conducted on the requirements for additional electricity supply in South Africa. Research showed that there is an urgent requirement for additional electricity supply to ensure continued economical growth. DSM was identified as one of the most favourable methods that could be implemented to address the problem. A reason for this is DSM projects are economically viable and can be implemented in a relatively short time. The initiative would also decrease the need for increasing electrical generation capacity.
During the research study important information regarding the computation process for load shifting and cost saving performance was gathered. Research was also conducted on the effect of DSM on labour and maintenance cost reduction, as well as economical engineering methods that can be used for alternative selection. The difference in performance between automated and manual systems was compared. The
results showed that a 40% improvement of automated systems over manual systems were attainable and sustainable. This will realise a total saving of approximately 45% in electricity costs for the client. Savings in labour and maintenance costs are shown to be achievable through the automation of pumping systems. These saving results were used in the Engineering Economic alternative selection methods where applicable. Economic calculations confirmed that automated projects are the most viable control method.
From the comparison study, it is shown that automated controlled systems are more
advantageous than manually controlled systems. It will therefore be in the best interest of the client to automate a manually controlled pumping system, as it will result in additional load shifting and cost saving. / Thesis (M.Ing. (Mechanical Engineering))--North-West University, Potchefstroom Campus, 2009.
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Researching the long-term impact of load management projects on South African mines / Nicolaas Cornelius Jacobus Marthinus de KockDe Kock, Nicolaas Cornelius Jacobus Marthinus January 2006 (has links)
Eskom is currently facing an energy crisis due to the limited operational electricity generating
capacity in South Africa. The historically low electricity price, the rapid growth in economy
and the energy intensive nature of South African industries are the most common reasons for
the peak supply problem.
Various supply and demand technologies have been identified to address this energy crisis.
Due to the lengthy process of building new peaking load power stations, Eskom has initiated
the Demand-side Management (DSM) programme as a solution to the short-term supply
problem.
The National Energy Regulator (NER) has set targets to Eskom DSM to reduce the evening
peak demand by 153 MW per annum and 4 255 MW over a 20-year planning horizon. Due to
the energy intensive nature of the mining industry, it has been targeted for DSM savings. To
date there have been a number of DSM projects implemented on the clear-water pumping
systems of various mines, with a large potential for DSM savings identified on future projects
still unrealised.
The generation benefit of DSM load-shifting projects is twofold; firstly Eskom's evening load
capacity increases due to the reduction in demand during these periods and secondly, the
mine receives electricity cost savings due to load management practices. Because Eskom
DSM is dependent on the client consumer to accept and roll-out the DSM programme, client
satisfaction is of paramount importance. Due to the fact that load-shifting efforts require from
the mine to change their normal operating schedules, there is uncertainty on the impact and
knock-on effects of DSM projects on a mine.
Therefore, the purpose of this study is to investigate and thereafter quantify the overall
impact of DSM load-shifting on the clear-water pumping system of South African mines. A
generic model was developed by performing case studies on existing DSM projects. This
model was then applied to future DSM projects to validate the findings made throughout the
research study.
The case studies performed on existing DSM projects, as well as the results obtained when
modelling the overall impact of DSM on future mines, proofs that DSM definitely benefits a
mine. The total annual cost saving on the four future DSM projects is predicted to be in the
order of R 7.64 million instead of the R 4.27 million when considering only the electricity cost
savings to the mine. / Thesis (M.Ing. (Electrical Engineering))--North-West University, Potchefstroom Campus, 2007.
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