Operational control of quality vegetables can be made using the method immitance control their electrical parameters.Vegetables – are objects of non-electric nature, and their juices – this electrolyte solutions, where there are free charged particles – ions, and it immitance method is based on measuring the electrical conductivity control objects. Therefore, research is relevant electrical parameters vegetable juices as well as development of electric and mathematical models immitance contact transducer. The object of the research is the process of measuring electrical parameters of objects of non-electrical nature. The study examined the features are measuring electrical parameters of the objects of nature electic primary contact transducers. The aim of the research is to identify the influence of parameters of contact transducers for measuring electrical parameters results electic nature objects in a frequency range test signal. Main tasks: – Make electric model quality control facilities electic nature; taking into account known today prototypes; – Make a mathematical model of quality control facilities electic nature; – Assess the impact of the model parameters (resistance and capacitance facility and capacity electrode layer) on the results of measurements of electrical parameters electic nature objects in a frequency range test signal. To study the electrical parameters of vegetable juice prepared generalized electrical equivalent circuit system “sensormeasuring tool”. Based on the equivalent circuit constructed system “sensor-measuring means” formed mathematical model of the transformer primary object of control. Informative electrical parameters are immitance components (active and reactive component) primary converter with vegetable juice (non-electric research object nature). Make up electrical and mathematical model of quality control objects non-electrical nature, taking into account known today prototypes and the results of experimental studies of changes active and reactive components of the conductivity (admittance) in the frequency range test signal. Using the experimental results of change of active and reactive components of the conductivity (admittance) using Solve Block in the software package MathCad Prime 3.1, values obtained resistance and capacitance object electic nature and capacity electrode layer in a frequency range test signal. Done mathematical modelling of admittance components with changes capacitance of electrode layer, resistance and capacitance of object non-electrical nature in a frequency range test signal. Processed obtained results of change of active and reactive components of the conductivity and provides guidance on the optimal frequency range of measurement and features of structural elements of the electrical model quality control objects non-electrical nature. The results of mathematical modeling components admittance was concluded that with increasing frequency electrode layer capacitance Cn frequency from which the active component is independent frequency decreases.And for independence measurement result object nature electic resistance Rx = 46 ohms and a capacity Cx = 1500 pkF (eg Carrot juice) at lower frequencies necessary to increase the capacity electrode layer, using a sensor with a greater area of the electrodes.Changing the capacity control object Cx does not affect the value immitance (this follows from the analysis of the expression of the active component of impedance as Cn >> Cx). Frequency from which reactive component is practically constant, slightly increases with increasing facility capacity control Cx. With the growing resistance of the control object Rx = 20, 40, 60, 80, 100 ohms (this range of resistance values corresponding to different vegetable juices) curves active component of impedance shifted downward by the value of active component of impedance and left in frequency, that frequency, from which the active component is independent frequency decreases. Therefore, for the independence of the measurement result object electic nature with less resistance required measurements at higher frequencies. However, with increasing resistance Rx frequency control facility from which the reactive component is practically constant, unchanged.
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