Elaboration and testing of the algorithm which ensures an achievement of minimal deviation angle of flying model’s main centroidal axis of inertia during her counterbalancing in a sole correction flatness

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High complexity and cost of developing flying models necessitate the use of such design and production techniques that would ensure the best flight technical and technological characteristics of the model also would raise of it operation effectivenessThese techniques include the experimental control method of flying models mass-inertia asymmetry parameters during final assembly of the modelSolution of the problem of optimization the process of bringing parameters of mass-inertia asymmetry of the conical flying model to specified standards is considered in the articleThe only correction plane is designed to be positioned close to cone faceaway from the center mass of the flying modelThe flying model as a component of prefabricated rotor is being balanced in dynamic mode on a low-frequency dynamic vertical standwhich based on gas bearingsBefore balancing experiment the weighlongitudinal center of mass and inertia moments of the flying model have to be controlled with use of another measurement equipment.  As a criterion of optimization is sorted the reaching of minimum of the angle of deviation of principal longitudinal centroidal axis of inertia from geometrical axis of the flying modelBut simultaneously the pre-set standard of center-mass shift from the geometrical axis must be ensuredBalancing algorithmeasy-to-realized by modern computersis presentedNumerical illustration of balancing is givenThe algorithm enables omitting intermediate steps of balancingreducing them to one step (as a rule), and shortening the balancing timeas wellIn one step of balancing the engineering model permits either bringing parameters of mass-inertia asymmetry of the flying model to specified standardsor diagnosing impossibility of attaining the specified standards with available design of flying model. The algorithm and balancing method are experimentally tested at newly-designed vertical dynamic stand on conical gas bearingsIts high precision and efficiency are corroborated.

作者简介

Mariya Filonova

Tomsk State University of Control System and Radio Electronics

编辑信件的主要联系方式.
Email: cmm91@inbox.ru

Cand. Sc., senior Researcher, Department of Radio Engineering Systems

俄罗斯联邦, 40, Lenina Av., Tomsk, 634050

参考

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