Mohammed Kishk scite author profile

Common maintenance strategies applied to wind turbines include 'Time-Based' which involves carrying out maintenance tasks at predetermined regular-intervals and 'FailureBased' which entails using a wind turbine until it fails. However, the consequence of failure of critical components limits the adequacy of these strategies to support the current commercial drivers of the wind industry. Reliability-Centred Maintenance (RCM) is a technique used mostly to select appropriate maintenance strategies for physical assets. In this paper, a hybrid of an RCM approach and Asset Life-Cycle Analysis technique is applied to Horizontal-Axis Wind Turbines to identify possible failure modes, causes and the resultant effects on system operation. The failure consequences of critical components are evaluated and expressed in financial terms. Suitable Condition-Based Maintenance activities are identified and assessed over the life-cycle of wind turbines to maximise the return on investment in wind farms. 1INTRODUCTION Wind is becoming one of the fastest growing energy sources in many countries seeking to mitigate the effects of global warming and reduce dependency on imported fuels. Very significant financial investments have been made in developing wind farms and the associated grid connection facilities all over the world. Indeed, the wind industry in 2005 spent more than US$14 billion on installing new generating equipment [1]. Progressively, world generated wind energy has now increased to about 59,322 MW [1] from 2,000 MW in 1990 [2] with an annual average growth rate of 26 percent [3]. With this growth has come the need to improve the productivity of wind turbines and to maximise the return on investment in wind farms. Successful future development will require maintenance strategies that are appropriate (technically feasible and economically viable over the lifecycle of wind turbines), given that, "the net revenue from a wind farm is the revenue generated from sale of electricity less operation and maintenance (O&M) expenditure" [4] This paper discusses the current maintenance strategies for wind turbines and identifies the associated problems. The concept and relevance of Reliability Centred Maintenance (RCM) and Asset Life-Cycle Analysis (ALCA) techniques to the wind energy industry are discussed and a Failure Modes and Effects Analysis of a generic horizontal axis wind turbine are presented. A case study is presented to demonstrate the practical application of the hybrid RCM and ALCA to determine suitable Condition Based Maintenance (CBM) activities for a 26x600 kW wind farm. The commercial viability of the CBM activities is assessed using the ALCA technique taking into account geographical location, intermittent operation and value of generation. Non-financial factors are identified and assessed using a Weighted Evaluation (WE) technique. Uncertainties in the financial calculations are risk assessed using a probabilistic technique of the Crystal Ball Monte Carlo simulation. 2RATIONALE AND OBJECTIVE Wind turbines ...

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Wind Turbine Maintenance Optimisation: Principles of Quantitative Maintenance Optimisation

Andrawus

Watson

Kishk

2007

Wind Engineering

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Maintenance optimisation is a crucial issue for industries that utilise physical assets due to its impact on costs, risks and performance. Current quantitative maintenance optimisation techniques include Modelling System Failures MSF (using monte-carlo simulation) and Delay-Time Maintenance Model (DTMM). The MSF investigates equipment failure patterns by using failure distribution, resource availability and spareholdings to determine optimum maintenance requirements. The DTMM approach examines equipment failure patterns by considering failure consequences, inspection costs and the period to determine optimum inspection intervals. This paper discusses the concept, relevance and applicability of the MSF and DTMM techniques to the wind energy industry. Institutional consideration as well as the benefits of practical implementation of the techniques are highlighted and discussed.

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Modelling System Failures to Optimise Wind Turbine Maintenance

2007

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Modelling System Failures (MSF) is a unique quantitative maintenance optimisation technique which permits the evaluation of life-data samples and enables the design and simulation of the system's model to determine optimum maintenance activities. In this paper, the approach of MSF is used to assess the failure characteristics of a horizontal axis wind turbine. Field failure data are collated and analysed using the Maximum Likelihood Estimation in the Weibull Distribution; hence shape ( β) and scale (η) parameters are estimated for critical components and subsystems of the wind turbine. Reliability Block Diagrams are designed to model the failures of the wind turbine and of a selected wind farm. The models are simulated to assess the reliability, availability and maintainability of the wind turbine and the farm; taking into account the costs and availability of maintenance crew and spares holding. Optimal maintenance activities are determined to minimise the total life-cycle cost of the wind farm.

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An Investigation into the Risk of Construction Projects Delays in the UAE

Motaleb

Kishk

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The growing rate of delays in project delivery is considered a major criticism of the construction companies in the United Arab Emirates (UAE). This paper aims to investigate the causes and effects behind the delays pertaining to delivery of construction projects in the UAE. The study is exploratory in nature, and incorporates a pilot questionnaire survey and interviews. An extensive literature review indicates potential factors that have possible effects on construction completion delay. The questionnaire forms were sent to 50 construction companies. Thirty-five (70%) completed responses were received. Analysis of the survey data has revealed that about 42 potential causes and effects of delay relate to various groups of stakeholders. The results show the top fifteen factors relate to clients, project managers and finance aspects. It was found that cost and time overruns are the most significant effects. These results are in partial agreement with previous studies. The paper argues that the key determinant in ensuring project control is on-time project delivery. The results of the study can provide moderate support for a suggested hypothesis, through a framework of project success factors. It should be of high concern to knowledge managers in various roles and decision-makers.

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Saudi Arabian Aviation Construction Projects: Identification of Risks and Their Consequences

Baghdadi

Kishk

2015

Procedia Engineering

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Mohammed Kishk

The Selection of a Suitable Maintenance Strategy for Wind Turbines

Wind Turbine Maintenance Optimisation: Principles of Quantitative Maintenance Optimisation

Modelling System Failures to Optimise Wind Turbine Maintenance

An Investigation into the Risk of Construction Projects Delays in the UAE

Saudi Arabian Aviation Construction Projects: Identification of Risks and Their Consequences

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