Scientific and Technical Journal


ISSN Print 2221-3937
ISSN Online 2221-3805
The problem of structural synthesis at complex technical systems creation, low methodological and information support problems of electromechanical objects and systems structural synthesis was analyzed. It was noted, that problem of system development methodologies structural synthesis of technical objects of arbitrary classes with the possibility of prediction is far from being resolved and remains in the technical sciences one of the most difficult and least studied. Highlights the necesity to move to a system methodology of synthesis, based on the use of structural genetic potential applications. Identified three system approaches to solving problems of analysis and synthesis genetically organized systems developing: geometrical (genus), group (topological) and genetic (species). These research areas are determined by periodic invariant structure and properties of Generated system of primary sources of electromagnetic fields. Shown group nature of structural homologics that define the relationship group properties of the primary sources of fields with genetically acceptable types of m-phase distributed winding and ending electromagnetic effects. These invariants determine metodology group synthesis using homeomorphic transformations. For example of electromechanical disintegrators functional class shown the implementation group innovative approach to solving the structural problems of prediction and synthesis for a given function purpose. It was shown that group method of synthesis inherent versatility and methodological unity, because the genetic structure of code arbitrary EM-object, apriori, containing information on his membership in a particular group and subgroup. The article presents the results of identification and analysis genetic program, through which first made predictions and group synthesis electromechanical disintegrators structures with maximum use of the active volume. According to the results of synthesis developed a set of competitive technical solutions new generation disintegrators. The results confirm the predictive function and high efficiency group method of synthesis in design of complex search tasks EM-systems technological purposes.
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