Motor Stator Winding – Structure Analysis in FMEA Example

The AIAG-VDA 7-Step FMEA approach recommends starting with a structure analysis that breaks down a system into system → subsystem → component levels.

To make this concept practical, let’s consider an electric motor and analyze its breakdown into stator and winding, which are critical for motor function and reliability.

👉 This example shows how Structure Analysis forms the foundation for later steps like Function Analysis (Step 3) and Failure Analysis (Step 4).

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Step 1: Define the System #

• System: Electric Motor Assembly
• Purpose: Convert electrical energy into mechanical rotation to power applications (e.g., vehicle propulsion, industrial equipment).

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Step 2: Identify Subsystems #

Within the electric motor, major subsystems include:

• Rotor (rotating part)
• Stator (stationary part with windings)
• Housing (protective casing)
• Bearings (support rotation)

For this example, we focus on the Stator Subsystem.

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Step 3: Break Down the Subsystem (Stator) #

The stator is the heart of the motor. It includes:

• Core (Laminations): Provides magnetic path.
• Windings (Coils): Carry current to generate magnetic field.
• Insulation: Prevents short-circuits.
• Slots & End Turns: Define winding placement and strength.

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Step 4: Component Level – Winding #

The winding is a critical component because it directly enables electromagnetic conversion.

• Function: Carry current and generate rotating magnetic field.
• Requirements:
  • Resistivity within design limits.
  • Thermal endurance (e.g., withstand 150°C).
  • Insulation strength to prevent shorting.
• Potential Failures:
  • Short circuit due to insulation breakdown.
  • Open circuit due to wire breakage.
  • Overheating due to excess current or poor cooling.

👉 By analyzing down to the winding level, the team ensures critical risks are captured early.

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Example Structure Tree – Motor → Stator → Winding #

Electric Motor (System)
│
├── Rotor (Subsystem)
│   ├── Shaft
│   ├── Magnets
│   └── Laminations
│
├── Stator (Subsystem)
│   ├── Core (Laminations)
│   ├── Windings (Component)
│   ├── Insulation
│   └── Slots
│
├── Housing (Subsystem)
│   ├── Covers
│   └── Seals
│
└── Bearings (Subsystem)
    ├── Inner Ring
    ├── Outer Ring
    └── Lubrication

📌 The breakdown helps identify interfaces (e.g., winding ↔ insulation, stator ↔ rotor) where many failures occur.

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Why This Example is Important in FMEA #

• Provides clarity on what is being analyzed (avoids confusion).
• Ensures critical components like winding are not overlooked.
• Builds traceability from system to component level.
• Creates a logical flow for moving into Function Analysis.

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Case Study – DFMEA for Electric Motor Winding #

• Function: Generate electromagnetic field.
• Requirement: Current capacity up to 20A, insulation withstand 150°C.
• Failure Mode: Short circuit in winding.
• Failure Effect: Motor fails, vehicle will not start.
• Severity: 9 (High).

👉 This shows how starting from structure analysis leads directly into function, failure, and risk analysis.

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Common Mistakes to Avoid #

• Stopping at the system level → missing critical component risks.
• Over-detailing → listing every screw or washer unnecessarily.
• Ignoring interfaces (e.g., rotor ↔ stator gap).
• Treating structure analysis as paperwork instead of a thinking process.

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Key Takeaways #

• Structure Analysis requires breaking down system → subsystem → component.
• In this example: Motor → Stator → Winding forms a clear traceable structure.
• Detailed breakdown helps ensure critical risks (like winding failure) are captured.
• This analysis feeds directly into Function Analysis (Step 3).

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Next Lesson #

👉 Continue with Lesson 3.4: Step 3 – Function Analysis