Overview
| Organizer | ITE Events Ltd. |
|---|---|
| Dates | From May 21st (Tuesday) to May 23rd (Thursday) 2019 |
| Location | Messe Berlin South Entrance (Berlin, Germany) |
| Booth Number | D10 /Hall 1.1 & A21 / Hall 3.1 |
| URL | https://powersys-solutions.com/events/event-detail/?type=conferences&eventid=885 |
CWIEME is known to be one of the world’s largest exhibitions of it’s kind, gathering products related to coil such as winding machines, motor stators and insulating paper.
The solutions that JMAG offers in design-based workflow for automobile motor drive systems will be presented using a large quantity of technical documents at the booth.
Those technical documents fall into nine categories.
- Machine Design
- Optimization
- High Accuracy & Speed
- Loss Analysis
- Thermal & NVH Analysis
- MBD
- Motor Control Simulation
- Automation & Parametric Study
- Transformer Design
What is required for a motor, which is the key component in vehicle electrification, is not only high performance as a component but also high conformance with the system.
Model-based development using simulations is also gradually becoming an indispensable tool for motor development.
JMAG, which has a proven track record in motor design, proposes a new workflow for model-based development.
Case studies demonstrated from content to be presented at the TECHNO-FRONTIER exhibition held in Makuhari, Japan, will be powered up and shown in Berlin.
We look forward to your participation.
Documents
Machine Design
- [L-MO-89] JMAG-Express Motor Design Tool
- [JAC008] Analysis of an Axial Gap Motor
- [JAC023] Eccentricity Analysis of an IPM Motor
- [JAC025] Analysis of a Claw Pole Alternator
- [JAC043] Torque Analysis of a Coreless Motor
- [JAC055] Integrated Magnetization Analysis of an IPM Motor
- [JAC068] Speed Versus Torque Characteristic Analysis of a Three-Phase Induction Motor
- [JAC074] Speed Versus Torque Analysis of a Single-Phase Induction Motor
- [JAC080] Cogging Torque Analysis of an SPM Motor with Skewed Magnetization
- [JAC082] Analysis of a Synchronous Reluctance Motor
- [JAC122] Inductance Analysis of an IPM Motor -d/q-axis Inductance Obtained by Actual Measurement-
- [JAC154] Calculation of Equivalent Circuit Parameters in a Three-Phase Induction Motor
- [JAC156] Segregation Analysis of Torque Components for an IPM Motor
- [JAC173] Basic Characteristic Analysis of an IPM Motor
- [JAC181] Analysis of SR Motor Drive Characteristics
- [JAC191] Torque Analysis of Three-Phase Induction Motors Accounting for the Skew Using the Multi-slice Method
- [JAC193] Calculation of Equivalent Circuit Parameters of Single-Phase Induction Motors
- [JAC195] Torque characteristics analysis of three-phase induction motors using 3D correction function
- [JAC196] Analysis of coil stray capacitance
- [JAC219] Axial Gap Type Motor Cogging Torque Analysis
- [JAC222] Irreversible Thermal Demagnetization Analysis of Incompletely Magnetized Magnets
- [JAC241] Single-Phase Synchronous Motor N-T-I Characteristics Analysis
- [JAC244] Magnetic Field Strength Analysis at a Sensor Position
Thermal & NVH Analysis
- [W-MO-23] Measurement of PM Motor Vibration/Noise and Analysis Modeling
- [W-VI-97] Correlation Analysis for Correcting Stiffness Using a Real Machine and an Analysis Model
- [L-MU-91]NVH analysis of EV drivelines with JMAG and RomaxDESIGNER
- [L-MU-93] JMAG/Adams/Simulink Coupled Vehicle Drive Simulation
- [JAC014] Inductance Analysis of a Bus Bar
- [JAC018] Thermal Analysis of a Motor
- [JAC019] Analysis of the Centrifugal Force in an IPM motor
- [JAC118] Thermal Analysis of a Bus Bar
- [JAC133] Thermal Analysis of a Three-phase Transformer
- [JAC138] 138 – Vibration Analysis of an SR Motor
- [JAC188] Thermal Demagnetization Analysis of IPM Motors Accounting for Coercive Force Distribution of Magnets
- [JAC205] Analyzing the Torque Characteristics of IPM Motors Using a Thermal Equivalent Circuit
- [JAC206] Temperature Analysis of an Oil-Immersed Transformer Using a Coupled Magnetic Field and Thermal Fluid Analysis
- [JAC208] High Frequency Induction Hardening Analysis Accounting for Deformation (Abaqus Link)
- [JAC220] Analysis of the High-Frequency Induction Hardening and Cooling of a Gear
- [JAC251] Alternator Vibration Analysis
- [JFT015] Procedure for Two Way Coupled Analysis with JMAG and STAR-CCM+ Taking Thermal Fluid into Account (Ver17.0 and After)
- [JFT021] Setting Magnet Material with Coercive Force Distribution and Residual Magnetic Flux Distribution Considering Temperature Dependence
- [JFT067] Preview of Output Electromagnetic Force Using the Multi-Purpose File Export Tool
Loss Analysis
- [W-TR-15] Loss Evaluation of a Transformer Shield Based on the Homogenization Method
- [W-MA-21] Iron Loss Analysis of an SR Motor Accounting for Hysteresis and Eddy Current Distribution
- [W-MA-46] Calculation Method of Eddy Current Loss of Electromagnetic Steel Sheet Using a 1D Finite Element Method
- [W-MA-49] Necessity and Approach of Stray Load Loss Analysis
- [W-MA-76] Material Modeling Method for Electromagnetic Field / Iron Loss Analysis Accounting for Residual Strain
- [W-MA-87] Verification of the Accuracy of Minor Loop Loss Using a Play Model
- [W-MA-100] Introduction of detailed analysis method of electrical steel sheet for high precision loss evaluation
- [W-MA-111] Modeling of anomalous eddy current loss in high precision iron loss analysis (2)
- [JAC087] Iron Loss Analysis of an IPM Motor Including the Effect of Shrink Fitting
- [JAC200] Iron Loss Analysis of IPM Motor using Hysteresis Model
- [JAC201] Iron Loss Analysis of an SR Motor
- [JAC202] Core Stray Loss Analysis of Power Transformer
- [JAC224] Wireless Power Transfer Device Stray Loss Analysis
- [JFT047] Performing Harmonic Loss Calculations with Current Control in JMAG-Designer
- [JFT060] Processing Measured Hysteresis Curves
- [JFT069] Performing Harmonic Loss Calculations Accounting for Current Control with JMAG-Designer and JMAG-RT
Motor Control Simulation
- [W-MB-63] Method for Determining the Optimum Resolution of JMAG-RT Model
- [W-MB-66] Accuracy Improvements in the JMAG-RT Induction Machine Model
- [W-SE-113] Reduction of calculation time using JMAG-RT model
- [L-MB-36] Highly-Accurate Estimation of Motor Behavior Using Detailed Motor Characteristics Obtained from JMAG-RT
- [L-MB-55]High Fidelity Behavior Models Generation for Control/Circuit Simulation using JMAG-RT
- [L-MB-79]Accounting for Circuit Coupling Functions with Control Systems
- [L-MO-108] Motor Performance Evaluation Considering Control
- [L-MU-110] Reaching Steady-State at an Early Stage Using a Control Circuit Containing a JMAG-RT Model
- [JAC090] Analysis of the Effect of PWM on the Iron Loss of an IPM Motor
- [JAC213] Circuit/Control Simulation of a Wound-Field Synchronous Motor
- [JAC214] Monitoring the Radial Force Acting on the Teeth of IPM Motors Using Circuit Control Simulation
- [JAC240] NT Characteristics Analysis of an IPM Motor Using PAM Drive
- [JFT068] Specifying Three-Phase Synchronous Motor dq Axis Current
- [JFT077] Creating JMAG-RT Models with Generic Circuit Topology
Automation & Parametric Study
- [L-MO-09] Easily Creating Complex Coil Ends Geometry in a Template
- [L-OP-107] Parameterize the number of poles and slots
- [JFT020] Inheritance of Analysis Content by Analysis Template
- [JFT022] File Export of a Physical Quantity by Multi-Purpose File Export Tool
- [JFT024] Remote Execution of Analysis Using SSH
- [JFT030] Procedure for Adding Cases with a Dimension as a Design Parameter (Parametric Analysis)
- [JFT031] Procedure for Adding Dimension Cases Using Equations (Parametric Analysis)
- [JFT034] Eccentricity Setting for Parallelly Offsetting the Rotation Axis
- [JFT037] Displaying Differences in Distributions
- [JFT038] Automation of JMAG using MATLAB
- [JFT062] Creating a Geometry Using a Geometry Template (Python)
- [JFT063] A Method for Performing Parametric Analysis on a Motor Using the Number of Poles and Number of Slots as Design Variables
- [JFT066] Coil Settings Using Winding Editor
- [JFT071] Creating User-Defined Calculation Components
High Accuracy & Speed
- [W-MA-51] Understanding Electromagnetic Phenomena in Steel Sheets Through Simulation
- [W-MA-70] Mesh Modeling for Coil AC Loss Analysis
- [W-HU-71] Notes on Performance Evaluation and Hardware Selection of JMAG Parallel Solver
- [W-SE-72] Reduction of Time Steps by Using Time Periodic Explicit Error Correction Method
- [W-SE-74] Electromagnetic Force Calculations Using the Adaptive Function
- [W-MA-88] Improvements in Accuracy of Anomalous Eddy Current Loss Calculations
- [W-SE-95] Improved durability of automatic mesh formation
- [W-SE-98] Improved durability of automatic mesh formation
- [W-SE-99] Acceleration of magnetic field analysis by SMP solver
- [W-SE-101] Detailed Eddy Current Analysis of End Winding with Parallel Processing
- [L-MO-90] Detailed Coil Modelling for Motors
- [L-SE-116] Accuracy improvement of calculation of electromagnetic force using correction
- [L-SE-117] Dealing with Non Conforming Mesh
- [JFT042] A Method for Obtaining a Steady-State Solution at an Early Stage (Time Periodic Explicit Error Correction)
- [JFT074] High Accuracy Electromagnetic Force Calculation with the Correction Method and Adaptive Mesh
Optimization
- [W-OP-96] Necessity of GA for multi-objective optimization of drive motor
- [L-OP-03] Multi-Objective Optimization with JMAG
- [L-OP-109] Exploration of new Ideas using Topology Optimization
- [JAC223] Multi-Objective Optimization of IPM Motors Considering Stress at High Rotation
- [JFT057] How to Run Topology Optimization
- [JFT075] Procedure for Dimensional Multi-Objective Optimization Calculations
- [JFT076] Methods for Running Geometry Optimization Using Multiple Studies
MBD
- [W-MO-85] Efficiency Map Evaluations Considering Harmonic Loss
- [W-MB-102] Motor efficiency map evaluation for Model-Based Development (MBD) using FEA simulation
- [W-MO-114] Measurement comparison of efficiency map
- [L-OP-25]Utilizing JMAG in Cloud Services
- [L-MO-105] System design for model-based efficiency map development (speed priority mode)
- [L-MO-106] Prototype and performance evaluation of Model-Based Development efficiency map (accuracy priority mode)
- [L-MO-115] Performance Evaluation of Induction Motors Using Efficiency Maps
- [JAC217] Creating Efficiency Maps for 3-Phase Induction Motors
- [JFT058] Creating Efficiency Map Using JMAG-Designer(Speed Priority)
- [JFT070] Creating Efficiency Maps Using JMAG-Designer (Accuracy Priority)
Transformer Design
- [JAC060] Superimposed Direct Current Characteristic Analysis of a Reactor
- [JAC086] Power Transmission Analysis of a Wireless Power Transfer System
- [JAC113] Power Transmission Analysis of a Wireless Power Transfer System with Opposing Cores
- [JAC132] Loss Analysis of a Three-phase Transformer
- [JAC151] Insulation Evaluation Analysis of a Power Transformer
- [JAC152] Electromagnetic Force Analysis of Short-circuited Power Transformer Coils
- [JAC185] Analysis of Stray Loss in a Power Transformer
- [JAC190] Arrangement Optimization of Wireless Power Transfer System
