BOND GRAPH BICAUSALITY MODELING THE HYDRAULIC SYSTEM

Abstract

This papers represents one of the most widely challenging control problems. The most accepted blockdiagrams in automatic control used to describe processes have been replaced by control based on bond graphmodeling. The bond graph model one physical model hydraulic process is presented. The goal of the research is toobtain a model of process with and without knowledge of the mathematical model, which is used to obtain asimulation and prediction model. Due to the feedback effect of the liquid in the pipes (power and flow), a bicausalbond graph was used as the flow source. Bond graphs have a basic concept in their physics - energy that isexchanged through connectors 0 and 1 (ports). Effort e (force, voltage, pressure, etc.) and flow f (current, velocity,volume, etc.) are general physical quantities that are used to analyze the appropriate physical model and descriptionfor bond graph modeling and that very successfully. Bond-graph modeling is a powerful tool for modelingengineering systems, especially when physical domains are involved. Submodels graph can be reused, because linkgraph models are not causal. Connection graphs are labeled and directed graphs, in which vertices representsubmodels and arrows represent the ideal energy connection between power ports. Bond has a direction of strengthand a direction of causality. The assigned computational causality dictates which port variable will be computed asthe result (output) and accordingly, another port variable will be the cause (input). Graphs can be connected to partsof the block diagram, submodels of the connection graph can have power connections, signal inputs and signaloutputs as their interface elements. Aspects such as the physical domain of the connection (energy flow) can be usedto support the modeling process. The research in this work is on obtaining a fast and adequate physical model withgood knowledge of physical changes.