Thermal Effects In Mechatronic Systems
Thermal Effects in Mechatronic SystemsThermal Effects in Mechatronics Systems - overview
ContentsMechatronics Training CurriculumDetails of Course Thermal Effects in Mechatronic SystemsThermal Effects in Mechatronics Systems - overview
Mechatronics Training CurriculumWorkshop Mechatronics System DesignPremiumAdvancedStandardOn requestAdvancedMotionControlAdvancedFeedforward &LearningControlPassiveDamping forHigh TechSystemsMasterclassDesignPrinciples5 days3 days3 daysOn requestMotionControlTuningDynamics andModellingDesignPrinciples forPrecision Eng.5 days3 days5 daysAdvanced Mechatronic System Design6 daysBasics andDesign forUltra CleanVacuum4 daysExperimentalTechniques inMechatronics3 daysMetrology &Calibration ofMechatronicSystems3 daysActuation andPowerElectronics3 daysMachineVision forMechatronicSystems2 daysThermalEffects inMechatronicSystems3 daysMechatronics System Design – part 25 daysBasicMechatronics System Design – part 15 daysStartwww.mechatronics-academy.nlThermal Effects in Mechatronics Systems - overviewRelevant partner trainings:Applied Optics, Electronics for nonelectrical engineers, System Architecture,Soft skills for technology professionals,
Mechatronics AcademyIn the past, many trainings were developed within Philips totrain own staff, but the training center CTT stopped.Mechatronics Academy B.V. has been setup to providecontinuity of the existing trainings and develop newtrainings in the field of precision mechatronics. It is foundedand run by:Prof. Maarten SteinbuchProf. Jan van EijkDr. Adrian RankersWe cooperate in the High Tech Institute consortium thatprovides sales, marketing and back office functions.Thermal Effects in Mechatronics Systems - overview
Thermal Effects in Mechatronic SystemsThermal Effects in Mechatronics Systems - overview
Course Director(s) / TrainersTeachers Dr.ir. T.A.M. Ruijl (MI-Partners) Ing. J. van der Sanden (ASML) Ir. Marco Koevoets (ASML) Dr.ir. Rob van Gils (Philips Innovation Services)Course Director(s) Dr.ir. T.A.M. Ruijl (MI-Partners) Dr.ir. A.M. Rankers (Mechatronics Academy)Thermal Effects in Mechatronics Systems - overview
ProgramDayContentsBasic Theory1LunchBasic Theory - continuedIntroduction to modeling techniques: building lump-mass models partRecap dayPrecise temperature measurements2Case CryoLunchCase, Cryo - continuedDesign for Thermal Stability Case ShieldingActive Thermal Control3LunchAdvanced Topics- model reduction / thermal modes / compensation & sensor placementThermal Effects in Mechatronics Systems - overview
Day 1 (morning): Basic TheoryHeat loadsTheory of heat transferTheory fluid flowTheory thermal deformationsTransient effectsVacuum aspectsThermal Effects in Mechatronics Systems - overview
Day 1 (afternoon): ModellingWhy lumped mass modelingSimple Lumped mass model exampleAnalysis and simulation using a state space descriptionStationary solutionTransient simulationFrequency domain analysisExercisessimple lumped mass model (deriving system matrices)effects of cooling wateranalyzing a temperature sensorThermal Effects in Mechatronics Systems - overview
Day 2 (morning): Temp. MeasurementSpot Sensor types:ThermocouplesResistance based sensorsRTD (Resistance Temperature Detector)Thermistor: NTC (Negative Temperature Coefficient)Performing Real MeasurementsFrom True to Observed valueReal Ideal Sensor ModelTemperature measurement of Solids/Liquids/GasDynamic behaviour, general remarksSensor CalibrationIR Temperature Meters:Principle and limitationsIR spot metersIR scanners/imaging systemThermal Effects in Mechatronics Systems - overview
Day 2 (morning/afternoon): CaseThermal Effects in Mechatronics Systems - overview
Day 2 (afternoon): Design for TEMSBasic design rules for precision equipmentStructural and metrology functionThermal design considerationsExample case: Ultra precision CMMSystem level design approachStructural and metrology functionThermal shieldingMetrology frame supportStatic versus transient behaviorMinimizing heat generation in manipulation systemThermal compensationShielding and enclosure (case)Thermal Effects in Mechatronics Systems - overview
Day 3 (morning): Active Thermal ControlThermal Effects in Mechatronics Systems - overview
Day 3 (afternoon): Advanced TopicsThermal Effects in Mechatronics Systems - overview
Sign-up for this trainingVia the website of our partnerHigh Tech InstituteThermal Effects in Mechatronics Systems - overview
Control 5 days On request Advanced Feedforward & Learning Control 3 days Premium Standard Basic Advanced Advanced Mechatronic System Design 6 days Actuation and Power Electronics 3 days Experimental Techniques in Mechatronics 3 days Metrology & Calibration of Mechatronic Systems 3 days Thermal Effects in Mechatronic Systems 3 days Machine
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worked systems based on dif-ferent technologies and their integration in hybrid solutions. Mechatronic specialists re-quire specific skills. The role of mechatronic specialists Mechatronic specialists ful-fil a crucial role in the design, development, production, installation and commissio-ning of new products, soft-ware, and production proces-
Key words: Systems engineering, modelling and simulation of mechatronic systems, model exchange, design process, flatness-based non-linear control, Electronic Stability Program. Complex mechatronic systems, for example brake or injection systems (ESP, Common Rail), consist of a large number of components from different physical domains.
mechanical systems of the 19th century to mechatronic systems in the 1980s. Fig. 2 shows the forward-oriented energy flow of mechanical energy converting systems (e.g., a motor) and the backward-oriented information flow, which is typical for many mechatronic systems. In this way, the digital electronic system acts on the process based on .
Currently, several systems can be considered as a mechatronic system due to the integration of the mechanical and elec-tronical elements in such systems. This is the reason why it is necessary to use new design methodologies, which consider integral aspects of the systems. The traditional approach for the design of mechatronic systems, considers
such as mechatronic systems, but also a type of fine control of modularity and several innovative GP search . mechatronic systems, a new approach is required (Youcef-Toumi [1]). The goal of the work reported in this paper . Based on the novel design methodology we have already developed to combine bond graphs and genetic programming, we .
complex mechatronic systems, analyze their transient and steady-state behavior, and front-load design decisions when integrating intelligent systems into your product. One-dimensional computer-aided engineering (1D CAE), also referred to as Mechatronic System Simulation, is multi-domain systems simulation in combination with controls. A concept
Cambridge IGCSE Accounting is accepted by universites and employers as proof of an understanding of the theory and concepts of accounting, and the ways in which accounting is used in a variety of modern economic and business contexts. Learners focus on the skills of recording, reporting, presenting and interpreting inancial information; these form an ideal foundation for further study, and for .
