VD
V.S.V. Dhanisetty
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6 records found
1
The long and therefore expensive training of aircraft maintenance technicians underline the need for accurate demand forecasts that allow for dynamic control of acquisition and training rate of personnel. This control enables human resource management to react swiftly to increases in workforce demand at times of technician shortages. To help human resource management a novel decision support model based on tactical demand forecasts in the aircraft maintenance context is proposed in this paper. Additionally, this paper presents a systematic research towards the optimal models to forecast tactical maintenance demand. The analysis is conducted using aggregated structural repair data of a fleet of wide-body passenger aircraft in the first ten years of its introduction. The results of this study show the potential of the proposed model as it is robust for varying amounts of non-constant workforce outflow and different fleet sizes. Furthermore, the model can be applied efficiently from one year after the acquisition of the first new aircraft. The novelty of this study is the direct integration of personnel training and acquisition with workforce demand forecasts. Additional research is recommended to validate the use of this model on other aircraft types, to explore the use of this model in the area of human resource management optimization and to extent this model to an organizational level
...
The long and therefore expensive training of aircraft maintenance technicians underline the need for accurate demand forecasts that allow for dynamic control of acquisition and training rate of personnel. This control enables human resource management to react swiftly to increases in workforce demand at times of technician shortages. To help human resource management a novel decision support model based on tactical demand forecasts in the aircraft maintenance context is proposed in this paper. Additionally, this paper presents a systematic research towards the optimal models to forecast tactical maintenance demand. The analysis is conducted using aggregated structural repair data of a fleet of wide-body passenger aircraft in the first ten years of its introduction. The results of this study show the potential of the proposed model as it is robust for varying amounts of non-constant workforce outflow and different fleet sizes. Furthermore, the model can be applied efficiently from one year after the acquisition of the first new aircraft. The novelty of this study is the direct integration of personnel training and acquisition with workforce demand forecasts. Additional research is recommended to validate the use of this model on other aircraft types, to explore the use of this model in the area of human resource management optimization and to extent this model to an organizational level
Bachelor thesis
(2020)
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T. P. S. Arblaster, X.F. van Beurden, C.F. van Winkel, H.H.J. de Goeijen, L.M. de Klerk, T.S. Lokken, P. Madabhushi, A.D.P. Schoon, M.G.M. van de Ven, W. A. J. G. de Vries, R.M. Vrouwes, S.J. Garcia Espallargas, V.S.V. Dhanisetty, G. Gonzalez Saiz, E. Mooij, J.A. Melkert
Bachelor thesis
(2020)
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J. Bertholdt, J.F. Bourgois, G. den Butter, V.A.B. Conings, S.A. McGinley, B. B. ODINOT, R. Smits, D. Tóth, D.G. van der Werff, M.H.G. Verkammen, C.A. Dransfeld, V.S.V. Dhanisetty
Bachelor thesis
(2019)
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C. Dos Santos Pereira Malveiro, L.K. Bajarūnas, T.J. Broertjes, M.J.M. van Nistelrooij, C. Özbek, A.M. Hekker, Tetsuya Watanabe, G. Kerkhofs, A.E. Grozeva, L.H. Rzeplińska, C.J. Simao Ferreira, S.J. Watson, V.S.V. Dhanisetty, M. Leandro Cruz
Modelling Impact Damage on Aircraft Structures (MIDAS)
Predicting impact damage on (composite) aircraft based on maintenance data of (metal) aircraft
In this thesis, a methodology is presented to predict impact damage on next-generation (composite) aircraft based on maintenance data of in-service (metal) aircraft. To achieve this conversion, an analytical model is developed to Model Impact Damage on Aircraft Structures (MIDAS) for composite (-C ) and metal (-M ) aircraft. The model characterizes impact threats based on damage dimensions in two steps. First, for a given specific threat an impact event is approximated, and the corresponding damage (i.e. the permanent dent) is estimated. Second, the analytical model is reverse engineered to deduce the impact threat characteristics from the permanent damage. MIDAS-M implements a new transition region between the local and global deformation modes based on penetration limits, while composite variant (MIDAS-C) provides a novel approach for the permanent indentation in the post fiber breakage region.
...
In this thesis, a methodology is presented to predict impact damage on next-generation (composite) aircraft based on maintenance data of in-service (metal) aircraft. To achieve this conversion, an analytical model is developed to Model Impact Damage on Aircraft Structures (MIDAS) for composite (-C ) and metal (-M ) aircraft. The model characterizes impact threats based on damage dimensions in two steps. First, for a given specific threat an impact event is approximated, and the corresponding damage (i.e. the permanent dent) is estimated. Second, the analytical model is reverse engineered to deduce the impact threat characteristics from the permanent damage. MIDAS-M implements a new transition region between the local and global deformation modes based on penetration limits, while composite variant (MIDAS-C) provides a novel approach for the permanent indentation in the post fiber breakage region.
Identification of strategic maintenance resource demand
A reliability based approach
Airline Maintenance and Engineering (M&E) organizations are faced with a number of repairs time to
time for their fleet of aircraft due to accidental damages. As these damages are unpredictable in nature,
the approach to repairing these damages is reactive. These type of repairs fall under the category of
corrective or unscheduled maintenance policy compared to the planned preventive or scheduled maintenance.
As the occurrence of these unscheduled repairs result in consumption of more maintenance
resources in an untimely manner, they add to the existing costs for the organisation. Hence, it is of
interest to the M&E to predict the demand for these resources for a future period so that the organisation
is better prepared to handle future maintenance activities. One of the resources impacted due
to unscheduled repairs is capacity, i.e maintenance hangar facility. If the capacity of a hangar facility
can be divided into certain number of slots, then prediction of the demand for these slots would
be beneficial to the maintenance planner. In order to identify the demand for these slots, it is first
important to forecast the trend of unscheduled repairs. To achieve this goal, i.e. prediction of future
repair and determination of slot capacity, a novel application for the integrated use of a reliability and
inventory control model has been identified in this thesis. Here, the concepts of inventory control has
been specifically applied to a maintenance application to determine the maintenance capacity by taking
into account the stochastic demand of unscheduled repairs. The model used to predict the demand
of unscheduled repair is a Non-homogeneous Poisson Process (NHPP) reliability model with a Power
law intensity function and the inventory control model that was found to be applicable is the singlesystem
single location Base-stock policy model. The reliability model considers the superpositioning
principle through which the failure behaviour for the entire fleet of aircraft could be predicted. Certain
performance measures were identified from the inventory control model, which helped in determining
capacity based on optimum costs as well as service level requirements. As a proof of concept, a study
is done on identifying the long-run capacity requirements for a fleet of Boeing 777 aircraft of a major
European airline. Two specific structural components were identified on which the study was carried
out, namely, the leading slats and the outboard flaps. The results showed the successful implementation
of the model by identifying 30 slots necessary in the next 1500 flight cycles at an optimum cost
for the case of leading edge slats.
...
Airline Maintenance and Engineering (M&E) organizations are faced with a number of repairs time to
time for their fleet of aircraft due to accidental damages. As these damages are unpredictable in nature,
the approach to repairing these damages is reactive. These type of repairs fall under the category of
corrective or unscheduled maintenance policy compared to the planned preventive or scheduled maintenance.
As the occurrence of these unscheduled repairs result in consumption of more maintenance
resources in an untimely manner, they add to the existing costs for the organisation. Hence, it is of
interest to the M&E to predict the demand for these resources for a future period so that the organisation
is better prepared to handle future maintenance activities. One of the resources impacted due
to unscheduled repairs is capacity, i.e maintenance hangar facility. If the capacity of a hangar facility
can be divided into certain number of slots, then prediction of the demand for these slots would
be beneficial to the maintenance planner. In order to identify the demand for these slots, it is first
important to forecast the trend of unscheduled repairs. To achieve this goal, i.e. prediction of future
repair and determination of slot capacity, a novel application for the integrated use of a reliability and
inventory control model has been identified in this thesis. Here, the concepts of inventory control has
been specifically applied to a maintenance application to determine the maintenance capacity by taking
into account the stochastic demand of unscheduled repairs. The model used to predict the demand
of unscheduled repair is a Non-homogeneous Poisson Process (NHPP) reliability model with a Power
law intensity function and the inventory control model that was found to be applicable is the singlesystem
single location Base-stock policy model. The reliability model considers the superpositioning
principle through which the failure behaviour for the entire fleet of aircraft could be predicted. Certain
performance measures were identified from the inventory control model, which helped in determining
capacity based on optimum costs as well as service level requirements. As a proof of concept, a study
is done on identifying the long-run capacity requirements for a fleet of Boeing 777 aircraft of a major
European airline. Two specific structural components were identified on which the study was carried
out, namely, the leading slats and the outboard flaps. The results showed the successful implementation
of the model by identifying 30 slots necessary in the next 1500 flight cycles at an optimum cost
for the case of leading edge slats.