Abstract
This paper addresses the challenge of developing an ontology for manufacturing process capability. This is an important task needed to achieve the semantical integration of various manufacturing planning and execution software and hardware (equipment) systems. The research presented has been performed within a framework of the Industrial Ontology Foundry (IOF) in which the authors are active participants. Manufacturing process capability is seen as a composition or combination of capabilities and functions of resources participating in the process. Theoretical foundation for the capability composition is presented. Individual participant resource functions are established using axiomatic design principles. The function and capability of the whole manufacturing processes is derived from individual resources using axiomatic design composition of functions. The overall approach is applied on example prismatic parts, their features, and simple machining processes. For each machining process, the machine tool brings one set of functions, while the cutting tool (mill or drill) brings its own functions. When combined for the manufacturing process those functions become capabilities in the whole process. The approach is illustrated on several feature geometries (holes, slots and pockets).
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Sarkar, A., Šormaz, D., Koonce, D., Farah, S. (2021). Developing a Resource-Based Manufacturing Process Capability Ontology. In: Rossit, D.A., Tohmé, F., Mejía Delgadillo, G. (eds) Production Research. ICPR-Americas 2020. Communications in Computer and Information Science, vol 1407. Springer, Cham. https://doi.org/10.1007/978-3-030-76307-7_22
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