Evaluation and Assessment of New Demand Response Products based on the use of Flexibility in Industrial Processes: Application to the Food Industry

Alcázar Ortega, Manuel

25 February 2011

En el marco de un mercado de la electricidad con precios cada vez más altos y donde la participación de fuentes renovables de generación está jugando un papel cada vez más importante, esta tesis supone un enfoque innovador hacia la participación de recursos de demanda en mercados de operación, prestando una atención especial a segmentos industriales como el sector alimentario con un consumo energético intensivo. En primer lugar, esta tesis describe detalladamente la situación actual de los programas de respuesta de la demanda que existen en diferentes partes del mundo. Este estudio permite concluir que los consumidores no han sido tenidos en cuenta suficientemente en la fase de diseño de los programas existentes, lo que ha provocado la infrautilización de recursos de demanda que, actualmente, permanecen sin explorar. Por otro lado, los consumidores no son conscientes del valor que su flexibilidad podría tener para el sistema eléctrico en su conjunto, ignorando que puedan existir otros agentes dispuestos a pagarles a cambio de reducir sus cargas en períodos determinados. Como resultado, esta tesis desarrolla una nueva metodología para explorar y valorar nuevos mecanismos de respuesta de la demanda donde el punto de vista de consumidores, operadores de red y cualquier otro agente interesado pueda ser tenido en cuenta. Esta metodología, basada en la evaluación y análisis detallado de los procesos, proporciona a los consumidores las herramientas adecuadas para evaluar su capacidad para reaccionar al precio de la electricidad, lo que permitiría al regulador poner en valor el beneficio social de dicha flexibilidad si pudiera ser utilizada en mercados de operación, ayudándole a definir los programas necesarios para utilizar de forma adecuada el potencial identificado por los consumidores. La metodología desarrollada en esta tesis ha sido aplicada satisfactoriamente al sub-segmento de la industria cárnica, por lo que varias fábricas pertenecientes a este segmento han sido estudiadas en detalle. En concreto, la factibilidad de las acciones propuestas ha sido probada y validada satisfactoriamente en una fábrica dedicada a la producción de jamón curado en España, en la que se han evaluado diferentes estrategias de flexibilidad. Finalmente, se ha realizado una evaluación económica de la rentabilidad de la aplicación de las acciones de flexibilidad propuestas tanto para el consumidor como para el sistema eléctrico en su conjunto, donde se han considerado los precios reales de los mercados de operación en España, aun cuando los consumidores no puedan participar realmente en dichos mercados en la actualidad. / Alcázar Ortega, M. (2011). Evaluation and Assessment of New Demand Response Products based on the use of Flexibility in Industrial Processes: Application to the Food Industry [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/10078

Demand side management

Food engineering

Load management

Power control

Power demand

Production management

INGENIERIA ELECTRICA

Avances en Verificación y Medida de la Respuesta de la Demanda y Aplicación a su integración en Smart Grids

Roldán Blay, Carlos

01 March 2016

[EN] The electric power industry is being shaken by a new idea that is taking shape: smart grids. Three aspects are considered keys to reach smart grids: a) The structure of the network must meet the smart grid concept, i.e. it must be resistant to failures, e.g. causing the automatic separation of any broken element without affecting the operation of the other components; it must be flexible to allow the connection or disconnection of loads and distributed generators, it must maintain efficient operation under various load conditions, and so on. b) The network should open the possibilities of participation of large and small generators as well as users, enabling new business opportunities and active participation, so that "intelligent" generation or consumption may benefit. c) All participants must have easy access to the information needed to choose the best operating strategy in each case. In regard to the first condition (a) there are significant challenges to solve: network automation, optimal design, development of new protection and control equipment, etc. It will be necessary to develop equipment adapted to new problems and new needs that will be generated in these networks. Those items of equipment should be standardised, it will be necessary to define tests to take into account issues that currently are not usually needed, such as the presence of disturbances in voltage, or others. In this sense, marginally though, the research team in which the author works has collaborated with a laboratory for electrical testing, the Flex Power Grid Lab Research Infrastructure DNV KEMA in the Netherlands, in the definition and implementation of some tests, as described in Chapter 3. Smart grids. In the second aspect (b), deep social changes are needed and, above all, regulation changes are crucial. In any case, the first step is to know how the consumption of loads is, how can demand be modified, how can small generation (mainly renewable) and energy storage influence generation, and so on. Having accurate models that provide this information is a key factor for network agents to establish their best strategies. This dissertation discusses many aspects of energy demand and the problem of controlling several resources and agents in the system operation is addressed and Chapter 3. Smart grids shows the management and control software (in which the author has collaborated during the design and development stages) of a small smart grid that exists in LabDER laboratory at UPV, where various resources are integrated according to the needs of demand, energy prices, and so on. In the third condition (c) there are also major challenges to be solved, such as mass information management and the increasing volume of data traffic that it can involve. This dissertation proposes several algorithms to facilitate treatment of the available data to optimise the management of the resources in a smart grid or to make decisions about the participation in demand response programs, as shown in Chapter 8. Energy Management Systems for Smart Customers. / [ES] La industria eléctrica de potencia está siendo sacudida por una idea que va tomando forma: las smart grids. Tres aspectos pueden considerarse claves para llegar a las smart grids: a) La estructura de la red debe responder al concepto de red inteligente, es decir, ser resistente a fallos, por ejemplo provocando la separación automática de cualquier elemento averiado sin afectar al funcionamiento del resto de la red; ser flexible para permitir la conexión o desconexión de cargas y generadores distribuidos, mantener un funcionamiento eficiente bajo diversos estados de carga, etc. b) La red debe abrir las posibilidades de participación de grandes y pequeños generadores así como de los usuarios, permitiendo nuevas posibilidades de negocio y de participación activa, de manera que la generación o el consumo "inteligentes" se vean beneficiados. c) Todos los participantes deben tener acceso fácil a la información necesaria para poder elegir la mejor estrategia de funcionamiento en cada caso. En lo que respecta a la primera condición (a) hay importantes retos por resolver: automatización de la red, diseño óptimo, desarrollo de nuevas protecciones y equipos de control, etc. Será necesario desarrollar equipos adaptados a los nuevos problemas y nuevas necesidades que se generarán en estas redes. Esos equipos deberán ser normalizados, para lo cual será necesario definir ensayos que tengan en cuenta aspectos que actualmente no suelen ser necesarios, como la presencia de perturbaciones en la tensión, u otros. En este sentido, aunque de forma marginal, se ha colaborado con un laboratorio para ensayos eléctricos, la Flex Power Grid Lab Research Infrastructure del DNV KEMA en los Países Bajos, en la definición y realización de algunos ensayos, como se indica en el Capítulo 3. Smart grids. En el aspecto segundo (b), son necesarios profundos cambios sociales y, sobre todo, legislativos. En cualquier caso, el primer paso consiste en saber cómo es el consumo de los receptores, de qué manera puede variarse la demanda, qué influencia puede tener la pequeña generación (renovable principalmente) y el almacenamiento de energía, etc. Disponer de modelos precisos que proporcionen esta información es clave para que los actores de la red puedan establecer sus mejores estrategias. En la tesis se analizan muchos aspectos relacionados con la demanda de energía y se aborda el problema del control de la participación de diversos recursos y diversos agentes en el funcionamiento del sistema y en el Capítulo 3. Smart grids se muestra el software de gestión y control (en cuyo diseño y desarrollo se ha colaborado) de una pequeña smart grid que existe en el laboratorio LabDER de la UPV, donde se integran diversos recursos en función de las necesidades de la demanda, los precios de la energía, etc. En la tercera condición (c) hay, también, grandes retos por resolver, como la gestión masiva de información y el incremento en el volumen de tránsito de datos que puede representar. En la tesis se proponen diferentes algoritmos para facilitar el tratamiento de los datos disponibles a la hora de optimizar la gestión de los recursos de una smart grid o tomar decisiones de cara a participar en programas de respuesta de la demanda, tal como puede verse en el Capítulo 8. Sistemas de Gestión Energética para Smart Customers. / [CA] La indústria elèctrica de potència està sent sacsada per una idea que va prenent forma: les smart grids. Tres aspectes poden considerar-se claus per a arribar a les smart grids: a) L'estructura de la xarxa ha de respondre al concepte de xarxa intel·ligent, és a dir, ser resistent a fallades, per exemple amb la separació automàtica de qualsevol element avariat sense afectar el funcionament de la resta de la xarxa; ser flexible per a permetre la connexió o desconnexió de càrregues i generadors distribuïts; mantindre un funcionament eficient davall diversos estats de càrrega, etc. b) La xarxa ha d'obrir les possibilitats de participació de grans i xicotets generadors així com dels usuaris. Així, ha de permetre noves possibilitats de negoci i de participació activa, de manera que la generació o el consum "intel·ligents" es vegen beneficiats. c) Tots els participants han de tindre accés fàcil a la informació necessària per a poder triar la millor estratègia de funcionament en cada cas. Pel que fa a la primera condició (a) hi ha importants reptes per resoldre: automatització de la xarxa, disseny òptim, desenrotllament de noves proteccions i equips de control, etc. Serà necessari desenrotllar equips adaptats als nous problemes i noves necessitats que es generaran en aquestes xarxes. Aqueixos equips hauran de ser normalitzats, per a la qual cosa serà necessari definir assajos que tinguen en compte aspectes que actualment no solen ser necessaris, com la presència de pertorbacions en la tensió, o altres. En aquest sentit, encara que de forma marginal, s'ha col·laborat amb un laboratori per a assajos elèctrics, la Flex Power Grid Lab Research Infrastructure del DNV KEMA en els Països Baixos, en la definició i realització d'alguns assajos, com s'indica en el Capítol 3. Smart grids. En l'aspecte segon (b), són necessaris profunds canvis socials i, sobretot, legislatius. En qualsevol cas, el primer pas consisteix a saber com és el consum dels receptors, de quina manera pot variar-se la demanda, quina influència pot tindre la xicoteta generació (renovable principalment) i l'emmagatzemament d'energia, etc. Disposar de models precisos que proporcionen aquesta informació és clau perquè els actors de la xarxa puguen establir les seues millors estratègies. En la tesi s'analitzen molts aspectes relacionats amb la demanda d'energia i s'aborda el problema del control de la participació de diversos recursos i diversos agents en el funcionament del sistema i en el Capítol 3. Smart grids es mostra el programari de gestió i control (en el disseny i desenrotllament del qual s'ha col·laborat) d'una xicoteta smart grid que existeix en el laboratori LabDER de la UPV, on s'integren diversos recursos en funció de les necessitats de la demanda, els preus de l'energia, etc. En la tercera condició (c) hi ha, també, grans reptes per resoldre, com ara la gestió massiva d'informació i l'increment en el volum de trànsit de dades que pot representar. En la tesi es proposen diferents algoritmes per a facilitar el tractament de les dades disponibles a l'hora d'optimitzar la gestió dels recursos d'una smart grid o prendre decisions de cara a participar en programes de resposta de la demanda, tal com pot veure's en el Capítol 8. Sistemes de Gestió Energètica per a Smart Customers. / Roldán Blay, C. (2016). Avances en Verificación y Medida de la Respuesta de la Demanda y Aplicación a su integración en Smart Grids [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/61302

Smart grids

Demand response

Measurement and verification

Energy efficiency

Demand side management

INGENIERIA ELECTRICA

Demand-Side Energy Management in the Smart Grid: Games and Prospects

El Rahi, Georges

26 June 2017

To mitigate the technical challenges faced by the next-generation smart power grid, in this thesis, novel frameworks are developed for optimizing energy management and trading between power companies and grid consumers, who own renewable energy generators and storage units. The proposed frameworks explicitly account for the effect on demand-side energy management of various consumer-centric grid factors such as the stochastic renewable energy forecast, as well as the varying future valuation of stored energy. In addition, a novel approach is proposed to enhance the resilience of consumer-centric energy trading scenarios by analyzing how a power company can encourage its consumers to store energy, in order to supply the grid’s critical loads, in case of an emergency. The developed energy management mechanisms advance novel analytical tools from game theory, to capture the coupled actions and objectives of the grid actors and from the framework of prospect theory (PT), to capture the irrational behavior of consumers when faced with decision uncertainties. The studied PT and game-based solutions, obtained through analytical and algorithmic characterization, provide grid designers with key insights on the main drivers of each actor’s energy management decision. The ensuing results primarily characterize the difference in trading decisions between rational and irrational consumers, and its impact on energy management. The outcomes of this thesis will therefore allow power companies to design consumer-centric energy management programs that support the sustainable and resilient development of the smart grid by continuously matching supply and demand, and providing emergency energy reserves for critical infrastructure. / Master of Science / The next-generation smart power grid is seen as a key enabler for effectively generating, delivering, and consuming electricity in a sustainable manner. Given the increasing demand for energy and the limited nature of various energy resources, the exchange of energy between producers and consumers must be optimally managed to pave the way towards the deployment of smart grid features on a larger scale. In particular, energy management schemes must deal with a complex and dynamic smart grid composed of utility companies, traditional power sources and loads, intermittent renewable energy generators, as well as new consumer-owned devices such as energy storage units and solar panels. In this thesis, we seek to model the different entities in the smart grid and the exchange of energy between them, in order to better understand the operation and effectiveness of various energy management schemes. In addition, this thesis accounts for the non-rational behavior of consumers in the energy trading process, when faced with various sources of uncertainty in the smart grid, including the intermittent renewable energy generation and the dynamic energy price. The results of this thesis will provide utility companies with key insights, crucial to the design of consumer-centric energy management programs, aimed towards matching electricity supply and demand, and insuring power supply to critical infrastructure.

Smart Grid

Demand-Side Management

Microgrid

Prosumers

Game Theory

Prospect Theory.

The rhythm of life is a powerful beat : demand response opportunities for time-shifting domestic electricity practices

Higginson, Sarah L.

January 2014

The 2008 Climate Change Act set legally-binding carbon reduction targets. Demand side management (DSM) includes energy use reduction and peak shaving and offers significant potential to reduce the amount of carbon used by the electricity grid. The demand side management (DSM) schemes that have tried to meet this challenge have been dominated by engineering-based approaches and so favour tools like automation (which aims to make shifting invisible) and pricing (which requires customer response) to shift demand. These approaches tend to focus on the tools for change and take little account of people and energy-use practices. This thesis argues that these approaches are limited and therefore unlikely to produce the level of response that will be needed in future. The thesis therefore investigates the potential for time-shifting domestic energy demand but takes a different angle by trying to understand how people use energy in their daily lives, whether this use can be shifted and some of the implications of shifting it. The centrepiece of the work is an empirical study of eleven households energy-use practices. The interdisciplinary methodology involved in-house observations, interviews, photographs, metered energy data and disruptive interventions. The data was collected in two phases. Initially, a twenty-four hour observation was carried out in each household to find out how energy was implicated in everyday practices. Next, a series of three challenges were carried out, aimed at assessing the implications of disrupting practices by time-shifting food preparation, laundry and work/ leisure. A practice theory approach is used to shift the focus of attention from appliances, tools for change, behaviour or even people, to practices. The central finding of this work is that practices were flexible. This finding is nuanced, in the light of the empirical research, by an extended discussion on the nature of practices; in particular, the relationship between practices and agency and the temporal-spatial locatedness of practices. The findings demonstrate that, in this study at least, expanding the range of demand response options was possible. The research suggests numerous possibilities for extending the potential of practices to shift in time and space, shift the energy used in practices or substitute practices for other non-energy-using practices, though there are no simple technological or behavioural fixes . More profoundly, however, the thesis concludes that infrastructures of provision , such as the electricity grid and the companies that run it, underpin and facilitate energy-use practices irrespective of the time of day and year. In this context technology-led demand response schemes may ultimately contribute to the problem they purport to solve. A more fundamental interrogation of demand and the infrastructures that serve it is therefore necessary and is almost entirely absent from the demand response debate.

333.79

Lastmanagement bei Haushaltskunden

Ouart, Sebastian

14 February 2017

Vor dem Hintergrund der Transformation der Energiewirtschaft wird in der Arbeit untersucht, wie eine prämienbasierte Nachfragesteuerung im Bereich der Haushaltskunden ausgestaltet werden kann, welche sowohl einen Beitrag zur Gewährleistung der Versorgungssicherheit leistet als auch für die beteiligten Akteure wirtschaftlich attraktiv ist. Zur Beantwortung der Fragestellung werden im theoretischen Teil der Arbeit die relevanten Aspekte der Stromwirtschaft, die Grundlagen der Nachfragesteuerung, die Preiselastizität der Nachfrage, die bestehenden Verfahren zur Initiierung von Lastveränderungen sowie Ansätze zur Ermittlung des Werts von der Versorgung mit elektrischer Leistung systematisch beschrieben. Aufbauend auf diesen theoretischen Grundlagen werden anschließend die konzeptionellen Anforderungen für die Ausgestaltung der Nachfragesteuerung erarbeitet, d. h. die Rahmenbedingungen analysiert, darauf aufbauend die Spezifikation für den Einsatz der Nachfragesteuerung vorgenommen und Vorgaben für die Produktgestaltung gemacht.

Transformation der Energiewirtschaft

Nachfragesteuerung von Haushaltskunden

Lastmanagement

Demand Side Management

Value of Lost Load

Versorgungssicherheit

Tarifgestaltung

Preiselastizität

Target Costing

Demand Side Management

Value of Lost Load

Target Costing

ddc:330

Energiewirtschaft

Management

Versorgungssicherheit

Tarif

Preiselastizität

Zielkostenrechnung

Lastmanagement bei Haushaltskunden: Ausgestaltung eines Konzepts zur prämienbasierten Nachfragesteuerung

Ouart, Sebastian

30 January 2017

Vor dem Hintergrund der Transformation der Energiewirtschaft wird in der Arbeit untersucht, wie eine prämienbasierte Nachfragesteuerung im Bereich der Haushaltskunden ausgestaltet werden kann, welche sowohl einen Beitrag zur Gewährleistung der Versorgungssicherheit leistet als auch für die beteiligten Akteure wirtschaftlich attraktiv ist. Zur Beantwortung der Fragestellung werden im theoretischen Teil der Arbeit die relevanten Aspekte der Stromwirtschaft, die Grundlagen der Nachfragesteuerung, die Preiselastizität der Nachfrage, die bestehenden Verfahren zur Initiierung von Lastveränderungen sowie Ansätze zur Ermittlung des Werts von der Versorgung mit elektrischer Leistung systematisch beschrieben. Aufbauend auf diesen theoretischen Grundlagen werden anschließend die konzeptionellen Anforderungen für die Ausgestaltung der Nachfragesteuerung erarbeitet, d. h. die Rahmenbedingungen analysiert, darauf aufbauend die Spezifikation für den Einsatz der Nachfragesteuerung vorgenommen und Vorgaben für die Produktgestaltung gemacht.

info:eu-repo/classification/ddc/330

ddc:330

Improved implementation strategies to sustain energy saving measures on mine cooling systems / Philip Mare

Maré, Philip

January 2015

Reliable, efficient and cost-effective energy supply is crucial for economic and social development. Mining and industrial sectors consumed close to 37% of the total energy produced in the world during 2013. The South African power network is strained by the rapid expansion of mining, industrial and public sectors. Generation, transmission and distribution of electrical energy are in progress, but supply will not meet demand in the near future. The South African electricity supplier needs capital for expansion. Electricity price increases have been significantly higher than increases in the gold price over the last few years. Mining companies are under pressure from government to improve their labour relations. They are obligated to spend money on local infrastructure development. Therefore, cost efficiency receives higher priority than ever before and requires an implementation strategy. Cooling systems on mines proved to be significant electricity consumers. These systems lack integrated management and efficient and optimised control. Electricity demand can be reduced through implementation of energy saving measures on these cooling systems. Energy saving measures reduce the operational costs of mining to ensure that mines stay globally competitive. The identification of long-term challenges for energy saving measures is crucial. Successful implementation of energy saving measures results in improved utilisation and performance of mine cooling systems. These measures must be maintained to ensure a constant positive impact on reduced electrical energy consumption. The electrical energy savings are dependent on external factors, such as ambient conditions. Improved implementation strategies of energy saving measures will prevent deterioration of utilisation and performance of the mine cooling systems. Monitoring and reporting of key performance indicators are crucial. Lack of integrated maintenance can lead to lost opportunities and the deterioration of equipment and machines. The improved implementation strategies in two separate case studies proved sustainable savings of 1.73 MW and 0.66 MW respectively. The electricity cost savings for Mine A and Mine B are R8.8 million and R2.9 million respectively. These savings have been sustained for periods of seventeen and seven months respectively, indicating the value of the study. / MIng (Mechanical Engineering), North-West University, Potchefstroom Campus, 2015

Mine cooling system

Cooling auxiliaries

Energy efficiency

Energy management

Electrical demand-side management

Variable water flow

Implementation strategies

The integrated effect of DSM on mine chilled water systems / Willem Schoeman

Schoeman, Willem

January 2014

The national electricity utility in South Africa, Eskom, is currently under pressure to supply the increasing demand for electricity on a national level. To address this problem in the short term, Eskom partially funds load management and energy efficiency projects. In the meantime, Eskom is also increasing their generation capacity through the erection of new power stations. To finance these capital projects, sharp tariff increases, higher than inflation, are levied, resulting in higher operating expenditures for the consumers. These increased tariffs are especially affecting industrial institutions. Large industries are therefore willing participants in the partially Eskom funded electricity savings programme that hold benefits for both parties. One of these large industries is the Mining Sector. This sector is an energy intensive group and consumes up to 15% of Eskom’s total output. The refrigeration and pumping systems used in the sectors are two of the major electricity consumers. As part of Eskom’s Demand Side Management (DSM) initiative, an electrical energy savings project was implemented in the deep mines’ chilled water systems. The cooling system is optimally controlled to ensure less underground water usage. This ensures that less water is pumped out by the dewatering system, reducing electrical energy usage. A variety of components, such as refrigeration and energy recovery depend on chilled water to function properly. Every relevant component was simulated and the verification of results was done through correlations with process data obtained from the mine. The simulation results showed acceptable error margins that would not influence accuracy. Two sites where a water supply optimisations project was implemented were selected as case studies. In both case studies, thermal results of the refrigeration and cooling system showed a reduction in cooling effectiveness. In case study A, the energy recovery components showed negative results. All of the results were converted to electrical energy costs to enable comparison. Constraints were evident during deep mine water supply optimisation. These were determined and the thermal effects were simulated. This study enabled basic quantifications of environmental impact and also determining project cost savings. The studies showed that positive and negative effects can be brought on in the mining systems with the reduction in chilled water use. In some cases the cooling system components showed a decrease in cooling effectiveness, but exhibited electrical energy savings. This impact was during periods where no personnel were underground in the working area. In conclusion the study also showed that cost savings resulting from the reduced chilled water are substantially higher than negative financial losses seen on the other components. / MIng (Electrical and Electronic Engineering), North-West University, Potchefstroom Campus, 2014

Chillled water

Reduction

Intervention

Deep mining

Cost

Demand Side Management

Simulation

Koue water

Vermindering

Intervensie

Diepmyn

Koste

Aanvraagkantbestuur

Simulasie

Improved implementation strategies to sustain energy saving measures on mine cooling systems / Philip Mare

Maré, Philip

January 2015

Reliable, efficient and cost-effective energy supply is crucial for economic and social development. Mining and industrial sectors consumed close to 37% of the total energy produced in the world during 2013. The South African power network is strained by the rapid expansion of mining, industrial and public sectors. Generation, transmission and distribution of electrical energy are in progress, but supply will not meet demand in the near future. The South African electricity supplier needs capital for expansion. Electricity price increases have been significantly higher than increases in the gold price over the last few years. Mining companies are under pressure from government to improve their labour relations. They are obligated to spend money on local infrastructure development. Therefore, cost efficiency receives higher priority than ever before and requires an implementation strategy. Cooling systems on mines proved to be significant electricity consumers. These systems lack integrated management and efficient and optimised control. Electricity demand can be reduced through implementation of energy saving measures on these cooling systems. Energy saving measures reduce the operational costs of mining to ensure that mines stay globally competitive. The identification of long-term challenges for energy saving measures is crucial. Successful implementation of energy saving measures results in improved utilisation and performance of mine cooling systems. These measures must be maintained to ensure a constant positive impact on reduced electrical energy consumption. The electrical energy savings are dependent on external factors, such as ambient conditions. Improved implementation strategies of energy saving measures will prevent deterioration of utilisation and performance of the mine cooling systems. Monitoring and reporting of key performance indicators are crucial. Lack of integrated maintenance can lead to lost opportunities and the deterioration of equipment and machines. The improved implementation strategies in two separate case studies proved sustainable savings of 1.73 MW and 0.66 MW respectively. The electricity cost savings for Mine A and Mine B are R8.8 million and R2.9 million respectively. These savings have been sustained for periods of seventeen and seven months respectively, indicating the value of the study. / MIng (Mechanical Engineering), North-West University, Potchefstroom Campus, 2015

Mine cooling system

Cooling auxiliaries

Energy efficiency

Energy management

Electrical demand-side management

Variable water flow

Implementation strategies

Potential of the implementation of demand-side management at the Theunissen-Brandfort pumps feeder

Motlohi, Khotsofalo Clement

2006 November 1900

Thesis (M. Tech.) - Central University of Technology, Free State, 2006 / Demand-side management (DSM) is one of the integrated energy planning concepts that has only recently been introduced in South Africa. This concept needs to be fully developed in order to suit current industrial development situations. South Africa’s coal and water reserves will not last forever because of the growing population and the accompanying demands on our energy resources {[5] of Chapter 1]}. Therefore the demand-side interventions are considered on an effective means of overcoming these problems. The traditional approach of electrical energy utilisation by Eskom and its customers has to be reviewed. Socio-economic and environmental development benefits must also be reviewed. Advanced research on demand-side management has benefited the international world tremendously and this kind of research should also be done in South Africa. The research project for this study as described from chapter 1- 8 was undertaken to show the potential implementation of demand-side management and its interventions (DSM programme) on the Theunissen-Brandfort Pumps 11kV feeder (TBP). This would result in the generating of potential energy and cost-savings that would flow from the feasible DSM programme. This would be measured and verified by billing the actual saved energy at the TBP electrical system for the future. Every potentially saved-energy means one less potential reduction in emission. The case studies were conducted on Eskom’s entire TBP network and on four large power users which were identified and which provided the relevant potential results. Methodological design protocol processes for best-practice pollution prevention and the efficiency-energy (EE) audit protocol model, with its accompanying goal and objectives were used. The project concentrated on EE and time-of-use (TOU) factors related to the selected customers and the TBP as a whole, thus: potential Replacement and Rewinding of low efficiency with higher efficiency motors and the TBP feeder potential Load-Shifting. The stages within the EE, LS and DSM project process which were used for potential implementation are the following: project identification, energy audits and assumptions and recommendations for implementation. The M&V interaction with DSM, EE or LS project processes (methodology) for future implementation purposes (actual retrofitting) is also shown. The TBP feeder collective baseline (Figure 6.2) was quantified by trapezium rule. The feasible EE and LS programmes opportunities analysis on motors and the entire TBP were performed by inference and stipulation techniques and the potential energy reduction effects using a simulation programme called International Motor Selection and Savings Analysis (IMSSA). The potential LS programme was also performed based on the Eskom’s miniflex tariff defined time of use. TBP plant-wide EE and LS assessments conducted with the methodology mentioned, identified and quantified a total of two EE savings opportunities and were divided into four categories: those for short-term, long-term, none and best solution potential implementations (Table 7.9). As far as indirect results are concerned, DSM is a very new concept in South Africa and is consequently not well known. The study was based on simplicity in order to make the DSM subject very simple and easily accessible to future research. By using a simple and userfriendly IMSSA software programme, quick, relevant results were obtained. The study played an important role in influencing and educating interested parties about the importance of potential demand-side management concepts and objectives. The study compiled valuable information on EE, DSM (LS) and M&V that was previously unknown and, which will make future research much more accessible and manageable. It is recommended that all the motors identified as inefficient be rewound and replaced by new and efficient ones in the future. It is also very important that the potential LS programme be implemented only after these potential EE opportunities are implemented so that there will be sustainability and the DSM objectives may be achieved (Table 7.10). The project led to better grasp of electric energy consumption by the customers. From a socio-economic perspective, Eskom can distribute the surplus potentially saved energy of capacity at the TBP to other communities, which would also create employment if a new network could be built. Allocation of potentially saved energy to other population groups or customers of low-income groups in the Theunissen area would mean a significant lifestyle change. With regard to environmental benefits, previous research has proven that for every kWh of electricity saved, fewer emissions (e.g. C02) would be generated at the power station. The study addressed TBP-wide power use, focusing primarily on the demand-side interventions, but implications for improvements in the supply-side emission reductions were also considered.