Life Cycle Management of a Construction Facility Ventilation System

Introduction. In the article a mechanical ventilation system is investigated by the author as a complex technical system, which can be efficiently managed based on its life cycle model. Like any engineering system (or a product, article of manufacture, project), a ventilation system has its own life cycle, consisting of a set of successive stages. Each stage is characterised by the types of work and final results attributed to it, which require managerial decisions. The study aims at developing a life cycle model of a ventilation system.

Materials and Methods. The life cycle analysis method of the complex technical systems, the methods of collecting and processing the statistical data, as well as the system and comparative analysis methods, and the method of synthesis of the scientific and practical results have been used in the research.

Results. Within the research conducted by the author, the "life cycle" approach to management of the ventilation systems had been implemented, and the objective of developing a life cycle model thereof, including all stages of system's evolution, from formation of a concept to disposal, had been achieved. Possible ways of managing the ventilation systems life cycle with respect to the uninterrupted interaction of processes had been defined.

Discussion and Conclusion. The efficient life cycle management of a mechanical ventilation system can be implemented through development of a software product capable of modeling the processes and elements of a system, starting from the very first stages of the life cycle. The software product will be able to eliminate the problem of inconsistencies existing at the different stages of work, will store the information about the object and provide access to it to each participant of the process. Solving the software development problem will ensure efficient management of the entire life cycle of a ventilation system, reduce the labour costs, eliminate the inconsistencies and ensure compliance with the modern requirements for the operational reliability and energy efficiency of the vital engineering systems.

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