160 likes | 417 Vues
Scheduling Periodic Maintenance of Aircraft through simulation-based optimization. Ville Mattila and Kai Virtanen Systems Analysis Laboratory, Helsinki University of Technology. Contents. The need for periodic maintenance (PM) scheduling Scheduling of PM tasks in the Finnish Air Force (FiAF)
E N D
Scheduling Periodic Maintenance of Aircraft through simulation-based optimization Ville Mattila and Kai Virtanen Systems Analysis Laboratory, Helsinki University of Technology
Contents • The need for periodic maintenance (PM) scheduling • Scheduling of PM tasks in the Finnish Air Force (FiAF) • A simulation-based optimization model for the scheduling task • Results from an example scheduling case
Aircraft usage and maintenance Usage Maintenance Pilot and tactical training, air surveillance A number of aircraft chosen each day to flight duty Several missions during one day Failure repairs Unplanned Periodic maintenance Based on usage Different level maintenance facilities
The need for PM scheduling • Scheduling is done for two primary reasons • Avoid degradation of aircraft availability • Allow maintenance facilities to plan for supply of resources
Difficulty of scheduling • Starting times of PM tasks can not be assigned with certainty • Timing depends on the maintenance interval and on the usage of the aircraft • Usage is affected by unexpected failures and subsequent repairs • Intervals are not adjusted during normal conditions
Maintenance schedule • A maintenance schedule consists of targeted starting times of PM tasks • The schedule is used to allocate flight time among aircraft by prioritizing aircraft with the highest ratio of • The allocation governs the accumulation of flight hours and the actual timing of PM tasks
The maintenance scheduling problem N the total number of aircraft X=(x1,1,...,x1,n1,...,xN,1,...,xN,nN) the maintenance schedule of the fleet L simulated average aircraft availability sample path
The simulation optimization model • A discrete-event simulation model • Describes aircraft usage and maintenance under a given maintenance schedule • Returns aircraft availability as output • A search method • Produces new schedules based on the simulated availabilities • A genetic algorithm (GA) or simulated annealing (SA)
A case example • The scheduling case • A fleet of 16 aircraft • A time period of 1 year • 4 of the aircraft each perform 4 daily flight missions • 4 PM tasks scheduled per each aircraft in the fleet • The performance of different configurations of GA and SA in the case are compared
Design of experiment • 300 evaluations of the simulation for each combination of parameters
Results • Highest average availability obtained in the optimization
Analysis of the obtained schedule • The simulation can be used to further assess the schedule obtained in the optimization • The queuing times in the maintenance facilities indicate whether the schedule can still be improved • The simulation also provides information on the distribution of times, when the PM tasks are actually materialized
Concluding remarks • The presented model has been implemented as a design tool for FiAF • Final validation can be conducted by comparing actual flight operations and maintenance with the simulation • Future work includes the consideration of task priorities in the optimization problem