Investing in land restoration in Manitoba

Hacault, Anais Gina Marie

18 January 2011

Tillage erosion is the dominant soil erosion process in hummocky landscapes. The topsoil lost from the convex upper slope positions (i.e., hilltops knolls, ridges) gradually makes its way to the concave lower slope positions (i.e., foot slopes, toe slopes/depressions), while reducing yield capability in the knolls. The accumulation of topsoil in the concave lower slope positions does not increase yield potential. Landscape restoration is a process by which organic-rich topsoil is removed from lower slope positions and is moved to the knoll positions where it is applied and incorporated as additional topsoil. Field studies on this matter have shown increases in crop yield productivity due to land restoration on the convex upper slope positions. Using a model developed in STELLA ®, this research examines the net monetary benefit of landscape restoration in specific landscape scenarios modeled after areas in Manitoba which are prone to tillage erosion. This study demonstrates that farming operations in hummocky landscapes, experiencing topsoil loss at knolls benefit from landscape restoration as it can lead to positive net returns. In this study, the research shows that landscape restoration, in the Rural Municipality of Lorne (South Western Manitoba), led to revenues greater than restoration costs for arable land used for agricultural purposes. Depending on soil conditions and tillage choices the payback period for landscape restoration ranged from 8 to 18 years.

Land Restoration

Cost Benefit Analysis

R.M. Lorne

Hummocky Landscape

Investment Decision

Payback Period

Investing in land restoration in Manitoba

Hacault, Anais Gina Marie

18 January 2011

Tillage erosion is the dominant soil erosion process in hummocky landscapes. The topsoil lost from the convex upper slope positions (i.e., hilltops knolls, ridges) gradually makes its way to the concave lower slope positions (i.e., foot slopes, toe slopes/depressions), while reducing yield capability in the knolls. The accumulation of topsoil in the concave lower slope positions does not increase yield potential. Landscape restoration is a process by which organic-rich topsoil is removed from lower slope positions and is moved to the knoll positions where it is applied and incorporated as additional topsoil. Field studies on this matter have shown increases in crop yield productivity due to land restoration on the convex upper slope positions. Using a model developed in STELLA ®, this research examines the net monetary benefit of landscape restoration in specific landscape scenarios modeled after areas in Manitoba which are prone to tillage erosion. This study demonstrates that farming operations in hummocky landscapes, experiencing topsoil loss at knolls benefit from landscape restoration as it can lead to positive net returns. In this study, the research shows that landscape restoration, in the Rural Municipality of Lorne (South Western Manitoba), led to revenues greater than restoration costs for arable land used for agricultural purposes. Depending on soil conditions and tillage choices the payback period for landscape restoration ranged from 8 to 18 years.

Land Restoration

Cost Benefit Analysis

R.M. Lorne

Hummocky Landscape

Investment Decision

Payback Period

Development of a capital investment framework for a gold mine / M. Clasen

Clasen, Mari

January 2011

This study was done against the backdrop that executives should carefully consider all the options to manage difficult periods before letting employees go, especially if they are going to rehire employees shortly after the economic recovery. Therefore, the study investigated whether investing in operational development of a plant can be used to increase feasibility, rather than to make across–the–board labour cuts. Two South African mining companies were chosen for this study. They are two investment centres at AngloGold Ashanti, Mine X Ltd. and Mine Z Ltd. The investigating project was done at Mine X to extract gold from the neighbouring Mine Z. Mine X will have access to the minerals 40 years in advance of Mine Z due to insufficient essential infrastructure at Mine Z. The life–time of the project is 18 years (estimated). The main objective of this study is to investigate the feasibility, from Mine X’s point of view, with a deepening project including Mine Z. The most significant aspect will be to determine which investment timeframe decision will gain Mine X a feasible position in terms of economic growth. This will be achieved by the following secondary objectives in making a capital investment decision: 1. To describe the nature and significance of investment decision making. 2. To recognise appropriate capital investment evaluation techniques in conjunction with sensitivity analysis. 3. To apply the techniques and sensitivity analysis in order to make a decision of a possible, feasible investment opportunity at Mine X. 4. To develop a framework to identify the project’s components and associate and access difficulties for Mine X‘s project lifecycle. The feasibility study undertakes multiple scenarios and provides recommendations and a final report, based on the scenario that is the most viable. The following techniques which were identified were used to analyse the feasibility of the project: Net present value, internal rate of return and payback period. All these above techniques will be analysed in three different scenarios, namely: 1. Mine X will stay with its current operations without any new projects. 2. The development project will begin immediately. 3. A six–month delay in development of the project. The study found that the net present value was positive, the internal rate of return was more than the discount rate and the payback period was shorter than the project’s life–time regarding to all three above–mentioned scenarios. The highest net present value is calculated in case the project starts immediately. Both the internal rate of return and the payback period indicated that a six month delay in the project is the most viable. After considering all the facts, the study concluded due to the highest net present value the best feasible recommendation would be to start the project immediately. The value of this study is that it is the first study to investigate the relationship between the viability to delay or to start the investment project immediately in the South African mining industry. This study is also unique, since it takes into account how mining industries world–wide can achieve long–term success through development projects without losing key players, due to impulsive short–term downsizing decisions. / Thesis (M.Com. (Management Accountancy))--North-West University, Potchefstroom Campus, 2012.

Capital evaluation techniques

Internal rate of return

Net present value

Payback periods

Sensitivity analysis

Feasibility study

Development of a capital investment framework for a gold mine / M. Clasen

Clasen, Mari

January 2011

This study was done against the backdrop that executives should carefully consider all the options to manage difficult periods before letting employees go, especially if they are going to rehire employees shortly after the economic recovery. Therefore, the study investigated whether investing in operational development of a plant can be used to increase feasibility, rather than to make across–the–board labour cuts. Two South African mining companies were chosen for this study. They are two investment centres at AngloGold Ashanti, Mine X Ltd. and Mine Z Ltd. The investigating project was done at Mine X to extract gold from the neighbouring Mine Z. Mine X will have access to the minerals 40 years in advance of Mine Z due to insufficient essential infrastructure at Mine Z. The life–time of the project is 18 years (estimated). The main objective of this study is to investigate the feasibility, from Mine X’s point of view, with a deepening project including Mine Z. The most significant aspect will be to determine which investment timeframe decision will gain Mine X a feasible position in terms of economic growth. This will be achieved by the following secondary objectives in making a capital investment decision: 1. To describe the nature and significance of investment decision making. 2. To recognise appropriate capital investment evaluation techniques in conjunction with sensitivity analysis. 3. To apply the techniques and sensitivity analysis in order to make a decision of a possible, feasible investment opportunity at Mine X. 4. To develop a framework to identify the project’s components and associate and access difficulties for Mine X‘s project lifecycle. The feasibility study undertakes multiple scenarios and provides recommendations and a final report, based on the scenario that is the most viable. The following techniques which were identified were used to analyse the feasibility of the project: Net present value, internal rate of return and payback period. All these above techniques will be analysed in three different scenarios, namely: 1. Mine X will stay with its current operations without any new projects. 2. The development project will begin immediately. 3. A six–month delay in development of the project. The study found that the net present value was positive, the internal rate of return was more than the discount rate and the payback period was shorter than the project’s life–time regarding to all three above–mentioned scenarios. The highest net present value is calculated in case the project starts immediately. Both the internal rate of return and the payback period indicated that a six month delay in the project is the most viable. After considering all the facts, the study concluded due to the highest net present value the best feasible recommendation would be to start the project immediately. The value of this study is that it is the first study to investigate the relationship between the viability to delay or to start the investment project immediately in the South African mining industry. This study is also unique, since it takes into account how mining industries world–wide can achieve long–term success through development projects without losing key players, due to impulsive short–term downsizing decisions. / Thesis (M.Com. (Management Accountancy))--North-West University, Potchefstroom Campus, 2012.

Capital evaluation techniques

Internal rate of return

Net present value

Payback periods

Sensitivity analysis

Feasibility study

Using a Financial Model to Determine Technical Objectives for Organic Solar Cells

Powell, Colin

27 July 2010

Organic solar cells (OSCs) are of interest because the technology offers a significant opportunity to reduce the overall costs of solar energy. OSCs can be very inexpensive to produce given that they rely on non-commodity materials and can use existing manufacturing techniques that are not labour- and capital-intensive. In this research, a financial model, named TEEOS (Technological and Economic Evaluator for Organic Solar), is developed and is used to determine financial indicators, such as simple payback period. These indicators are used to determine technical objectives for the OSCs. Two sample cells are evaluated in Toronto, Canada using historical data. The results show that the cell with a higher efficiency and wider absorptive wavelength range produces a payback period of approximately nine years, while the other cell has a payback period well over 45 years. Stochastic modeling techniques are also used to better replicate electricity price and weather fluctuations.

Solar Energy

Organic Solar Cells

Payback Period

Toronto

Net Present Value

0542

Using a Financial Model to Determine Technical Objectives for Organic Solar Cells

Powell, Colin

27 July 2010

Organic solar cells (OSCs) are of interest because the technology offers a significant opportunity to reduce the overall costs of solar energy. OSCs can be very inexpensive to produce given that they rely on non-commodity materials and can use existing manufacturing techniques that are not labour- and capital-intensive. In this research, a financial model, named TEEOS (Technological and Economic Evaluator for Organic Solar), is developed and is used to determine financial indicators, such as simple payback period. These indicators are used to determine technical objectives for the OSCs. Two sample cells are evaluated in Toronto, Canada using historical data. The results show that the cell with a higher efficiency and wider absorptive wavelength range produces a payback period of approximately nine years, while the other cell has a payback period well over 45 years. Stochastic modeling techniques are also used to better replicate electricity price and weather fluctuations.

Solar Energy

Organic Solar Cells

Payback Period

Toronto

Net Present Value

0542

Ranking of Energy Saving Devices for Smart Homes according to their Payback Time

Felderer, Astrid, Brandtweiner, Roman, Hoeltl, Andrea

January 2018

This paper discusses the average energy savings of various smart devices in connection with their average price. By calculating the devices' payback times, a ranking of the tools can be given. The whole study focuses on the average household within the EU-28 in terms of climate as well as in terms of user behaviour. The purpose of the research was to provide a win-win situation for users' wallets and the environment by showing the device which suits both players best. As a result of the research, it was found that the greatest reduction in energy consumption can be reached by an interaction of the smart device and the inhabitants of a smart home. By giving users feedback on their energy consumption through smart meters, average savings of 7.5% are reached. As a smart meter is available for about Euro 80, it has a payback time of only 4.24 months.

Eficiência energética em uma indústria química : analíse de projeto de investimento

Wei, Chang Chung

January 2015

Orientador: Prof. Dr. Douglas Alves Cassiano / Dissertação (mestrado) - Universidade Federal do ABC. Programa de Pós-Graduação em Energia, 2015. / A energia é um componente importante na sociedade moderna, e é praticamente impossível dissociar-se da energia com o modo de vida ou atividade econômica existente. No entanto, devido ao recurso energético limitado e a tecnologia disponível, a eficiência energética passa a ser uma das tendências mais importantes no uso desse recurso energético. No setor industrial, a energia usualmente não é utilizada de maneira direta, mas sim no acionamento de equipamentos e sistemas que proporcionam conforto e produção. No segmento químico há grande demanda desse recurso energético, pois muito processos requerem energia em diversas formas. O presente trabalho teve por objetivo a análise e avaliação de um projeto de eficiência energética implantado em uma unidade de produção de água resfriada de uma indústria química. Foi efetuada uma auditoria energética inicial, avaliando-se aspectos técnicos e de operação dos equipamentos para identificação das possibilidades de aumento da eficiência energética. As informações obtidas desta auditoria serviram para fundamentar as análises de investimento neste projeto, previamente a sua implantação, utilizando-se indicadores como Payback, Taxa Interna de Retorno (TIR) e o método do Valor Presente Líquido (VPL), assim como uma análise de sensibilidade destes. Após a implantação do projeto de eficiência energética, efetuou-se outra nova auditoria energética para fins de comparação, obtendo-se uma variação de 37,42% entre os valores projetados e executados. / Energy is an important component in modern society, and it is practically impossible to dissociate energy with the way of life or economic activity there. However, due to limited energy resource and technology available, energy efficiency becomes one of the most important trends in the use of this energy resource. In the industrial sector, energy is usually not used directly, but rather in the firing equipment and systems that provide comfort and production. In the chemical industry, there is great demand of this energy resource, because processes require energy in many ways. The present work aimed the analysis and evaluation of an energy efficiency project implemented in a chilled water production unit in a chemical plant. An initial energy audit was performed, evaluating technical aspects and operation of equipment to identify the possibilities for improving energy efficiency. The information from this audit served to support the investment analysis in this project, prior to its implementation, using indicators such as Payback, Internal Rate of Return (IRR) and the method of Net Present Value (NPV) as well as an analysis of sensitivity thereof. After the implementation of energy efficiency project, another energy audit was performed for comparison purposes, resulting in a variation of 37.42% between the projected and executed values.

EFICIÊNCIA ENERGÉTICA

INVESTIMENTOS - ANÁLISE

PAYBACK

ENERGY EFFICIENCY

INVESTMENT ANALYSIS

HTLS UPGRADES FOR POWER TRANSMISSION EXPANSION PLANNING AND OPERATION

January 2014

abstract: Renewable portfolio standards prescribe for penetration of high amounts of re-newable energy sources (RES) that may change the structure of existing power systems. The load growth and changes in power flow caused by RES integration may result in re-quirements of new available transmission capabilities and upgrades of existing transmis-sion paths. Construction difficulties of new transmission lines can become a problem in certain locations. The increase of transmission line thermal ratings by reconductoring using High Temperature Low Sag (HTLS) conductors is a comparatively new technology introduced to transmission expansion. A special design permits HTLS conductors to operate at high temperatures (e.g., 200oC), thereby allowing passage of higher current. The higher temperature capability increases the steady state and emergency thermal ratings of the transmission line. The main disadvantage of HTLS technology is high cost. The high cost may place special emphasis on a thorough analysis of cost to benefit of HTLS technology im-plementation. Increased transmission losses in HTLS conductors due to higher current may be a disadvantage that can reduce the attractiveness of this method. Studies described in this thesis evaluate the expenditures for transmission line re-conductoring using HTLS and the consequent benefits obtained from the potential decrease in operating cost for thermally limited transmission systems. Studies performed consider the load growth and penetration of distributed renewable energy sources according to the renewable portfolio standards for power systems. An evaluation of payback period is suggested to assess the cost to benefit ratio of HTLS upgrades. The thesis also considers the probabilistic nature of transmission upgrades. The well-known Chebyshev inequality is discussed with an application to transmission up-grades. The Chebyshev inequality is proposed to calculate minimum payback period ob-tained from the upgrades of certain transmission lines. The cost to benefit evaluation of HTLS upgrades is performed using a 225 bus equivalent of the 2012 summer peak Arizona portion of the Western Electricity Coordi-nating Council (WECC). / Dissertation/Thesis / M.S. Electrical Engineering 2014

Engineering

Electrical engineering

Chebyshev inequality

Economic efficiency

High Temperature Low Sag

Payback period

Transmission upgrades

Zdroje financování a hodnocení dopadů zateplení budov školských zařízení / The sources of financing and evaluation the insulation of school facilities

Fidler, Josef

January 2013

The thesis is focused on the evaluation of the consequences of building insulation educational facilities. The aim is to determine whether the construction insulation manifest themselves in the cost management of school facilities as well as in the cost management of the town district, which is their legal founded. Source data of the thesis are energy audits, documents containing data on actual heat consumption, publicly available data on the financial statements of educational facilities and district budgets. The final results confirmed that the insulation brought a positive impact on both the cost management of the surveyed kindergartens and the cost management of the district. So, the investment into insulation was spent effectively. This is also evidenced by the results of the payback period and net present value.