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[JAC181] Analysis of SR Motor Drive Characteristics
This example presents how to confirm drive characteristics such as torque, loss, and efficiency in a motor when its switch timing changes for each rotation speed.
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[JAC202] Core Stray Loss Analysis of Power Transformer
This document introduces runs analysis by modeling the short-circuit test that is conducted when evaluating stray loss and obtains stray loss distribution in the core close to the…
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[JAC195] Torque characteristics analysis of three-phase induction motors using 3D correction function
This document introduces introduces a case study which obtains inductance correction values, and then obtains N-T characteristics (revolution speed-torque characteristics) using t…
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[JAC167] Iron Loss Analysis of a Three Phase Induction Motor
This Application Note presents an example of how to find the iron loss in the stator core and rotor core at a rotation speed of 3,300 r/min.
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[L-MB-33]Supporting Motor Drive Development with a JMAG-MATLAB/Simulink Coupling
Together with Mathworks, the company that develops MATLAB/Simulink (hereafter referred to as "Simulink"), JMAG strongly supports model-based development (hereafter referred to as …
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[L-MO-29] Creating Efficiency Maps with JMAG (FEA)
JMAG now offers a tool which uses finite element analysis (FEA) calculations to output an efficiency map. The advantage of using FEA to calculate an efficiency map is accuracy. In…
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[L-MB-32] Simulating Responsiveness of Electric Machinery During Control with High Accuracy Using a Direct Coupling Analysis
For machines requiring high-speed responsiveness for controllers such as solenoid valves and injectors, level of accuracy required in simulation have increased following the advan…
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[L-MB-28] The Incorporation of JMAG into Model Based Design
The JMAG-provided plant model (JMAG-RT) simulates the characteristics of an actual machine with high-fidelity information, acquired by means of FEA, and realizes a highly reliable…
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[RTML-001] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 54(mm) | Height: 51(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(Vshaped) | Average torque: 3.6(N·m)
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[RTML-002] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 54(mm) | Height: 54(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(flat) | Average torque: 3.6(N·m)
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[RTML-003] PMSM/SPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 53(mm) | Height: 36(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: SPM | Average torque: 3.6(N·m)
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[RTML-004] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 54(mm) | Height: 77(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(Vshaped) | Average torque: 3.6(N·m)
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[RTML-005] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 54(mm) | Height: 80(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(flat) | Average torque: 3.6(N·m)
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[RTML-006] PMSM/SPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 53(mm) | Height: 46(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: SPM | Average torque: 3.6(N·m)
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[RTML-007] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 115(mm) | Height: 20(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(Vshaped) | Average torque: 3.6(N·m)
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[RTML-008] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 115(mm) | Height: 22(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(flat) | Average torque: 3.6(N·m)


