The consistency problem caused by uncertainties in manufacturing process is a significant factor influencing the quality of electromechanical components. Currently, there are two approaches for reducing the influence of uncertainties. The first one is to improve the resistance capability of design scheme by using robust parameter design( RPD) method with nonlinear feature of controllable factors. The second one is to control the influence of uncertainties by using robust tolerance design( RTD) method with quality loss function,setting the optimal tolerance with the minimum total product loss as the objective. However, as for the electromechanical component, it is difficult to achieve nonlinear region owing to the restrictions of design parameters. In addition,the establishment of cost function in manufacturing process is also confronted by practical difficulties. In order to solve the quality consistency problem under the influence of manufacturing uncertainties,a novel tolerance design method was proposed for the electromechanical components. Through the experiment design and contribution rate analysis, key factors influencing the quality consistency were determined,and the tolerance allocation scheme was confirmed according to the consistency objective of quality.Then, quality distribution characteristics before and after the consistency optimization were analyzed and verified through the Monte Carlo stochastic simulation. The application result of electromagnetic relay proves the effectiveness of the method proposed in this paper.
As for aerospace electromagnetic relay (AEMR) which is of small batches and having difficulty in automatic production, the uncertainty phenomenon is remarkable due to excessive manual work involved in the assembly and adjustment processes. This kind of uncertainty may increase the coil voltage difference (CVD) caused by hesitate phenomenon in the pick up process of AEMR. Taking a certain type of AEMR for example, the CVD problem in the actual producing process has been studied in this paper. The primary cause of this issue, two-steps of armature motion (namely hesitate phenomenon) in the pick up process, has been found by analyzing the matching characteristics of electromagnetic and mechanical torques of AEMR. Through the optimization of the matching characteristics, the two-steps of armature motion problem is solved by robust design of the return reed which is a key part of AEMR. The validity of this research has been proved by the comparison of characteristics of AMER before and after the optimization.
