01 Basic Principles of the Generating Method

1.1 Mathematical Foundations

• Enveloping Principle: The movement trajectory of the cutting edge of tools (such as hobs and gear shapers) forms a series of continuous curves, and the envelope of these curves constitutes the theoretical gear tooth profile (e.g., involute, cycloid).
• Meshing Equation: Satisfies the relative motion relationship between the tool and the workpiece to ensure tooth profile accuracy.

1.2 Key Characteristics

• High Precision: Capable of machining complex tooth profiles (e.g., involute, circular arc gears).
• High Efficiency: Continuous cutting enables mass production.
• Strong Versatility: A single tool can machine gears with different numbers of teeth (provided they have the same module).

1.3 Typical Generating Method Processes

1.3.1 Hobbing

• Principle: Utilizes the meshing motion between a hob (resembling a worm in shape) and the gear blank, completing cutting through axial feed.
• Motion Relationship: Hob rotation (main cutting motion) + Workpiece rotation (generating motion) + Axial feed.
• Advantages: High efficiency, suitable for mass production (e.g., automotive gears); can machine spur gears, helical gears, worm gears, etc.
• Application Examples: Machining of planet gears and sun gears in wind power gearboxes.

1.3.2 Gear Shaping

• Principle: Uses a gear shaper cutter (similar in shape to a gear) to perform reciprocating cutting motion on the workpiece while rotating at a meshing ratio.
• Motion Relationship: Vertical reciprocating cutting of the gear shaper + Generating rotation of the workpiece and tool.
• Advantages: Can machine complex structures such as internal gears and double gears; superior tooth surface roughness compared to hobbing (Ra 0.8–1.6 μm).
• Limitations: Lower efficiency than hobbing; higher tool cost.
• Application Examples: Machining of internal gear rings in gearboxes and small precision gears.

1.3.3 Gear Shaving

• Principle: The shaving cutter and workpiece rotate in mesh under slight pressure, improving tooth profile accuracy through the scraping action of the cutter edges. It is a finishing process used for trimming after hobbing or gear shaping.
• Advantages: Can correct tooth profile errors and enhance gear transmission smoothness; machining accuracy reaches DIN 6–7 grade.
• Application Examples: Final machining of automotive gearbox gears.

1.3.4 Gear Grinding

• Principle: Uses a formed grinding wheel or worm grinding wheel to grind the tooth surface through generating motion, mainly for finishing hardened gears.
• Advantages: Extremely high precision (up to DIN 3–4 grade); can machine hard-tooth-surface gears (HRC 58–62).
• Limitations: High cost and low efficiency, typically used in high-precision demand fields.
• Application Examples: Aerospace engine gears and high-speed stage gears in wind power gearboxes.

02 Basic Principles of Form Cutting

• High Tool Dependence: Tooth profile accuracy directly depends on tool contour precision.
• No Generating Motion: The machining process does not simulate gear meshing, relying only on the relative motion between the tool and the workpiece.
• High Flexibility: Capable of machining non-standard tooth profiles (e.g., circular arc teeth, rectangular teeth).

2.1 Mathematical Foundations

• Profiling Principle: The geometric shape of the tool's cutting edge perfectly matches the gear tooth space.
• Indexing Motion: Uses indexing devices (e.g., dividing heads) for tooth-by-tooth machining to ensure uniform tooth pitch.

2.2 Advantages and Disadvantages

Advantages

• Simple Equipment: Achievable with ordinary milling machines.
• Suitable for Single-Piece, Small-Batch Production or Repair: Ideal for customization and maintenance scenarios.
• Capable of Machining Extra-Large Module Gears: Such as gears used in mining machinery.

Disadvantages

• Low Precision: Typically DIN 9–10 grade.
• Low Efficiency: Requires tooth-by-tooth machining.
• Poor Tool Versatility: Specialized tools are needed for each module.

2.3 Typical Form Cutting Processes

2.3.1 Gear Milling

• Principle: Uses a disc milling cutter or end mill; the cutter rotates for cutting, and the workpiece is indexed tooth by tooth via a dividing head.
• Motion Relationship: Cutter rotation (main cutting) + Workpiece axial feed + Indexing rotation.
• Application Scenarios: Single-piece and small-batch production of spur gears and helical gears; large-module gears (module ≥20 mm) or repair gears.
• Case Study: Low-speed stage gears of marine reducers (module 30, material: 42CrMo) processed by end mill + CNC indexing, achieving a tooth surface roughness of Ra 3.2 μm.

2.3.2 Gear Broaching

• Principle: Uses a broach (a multi-tooth stepped tool) to broach the entire tooth space in one pass.
• Motion Relationship: Linear motion of the broach (cutting) + Fixed workpiece.
• Advantages: Extremely high efficiency (completes one tooth space per stroke); relatively high precision (up to DIN 7 grade).
• Limitations: Only suitable for mass production of internal or external gears; high broach manufacturing cost, ideal for large-volume orders of a single specification.
• Application Examples: Mass production of automotive synchronizer rings (cycle time <10 seconds/piece).

2.3.3 Form Grinding

• Principle: Uses a formed grinding wheel (with a contour matching the tooth space) to grind hardened gears.
• Motion Relationship: Grinding wheel rotation + Workpiece indexing.
• Advantages: Can machine high-hardness gears (HRC >60); precision up to DIN 4 grade (tooth profile error <5 μm).
• Application Fields: Finishing of aerospace engine gears and precision reducer gears.

03 Comparison and Industrial Applications of the Two Methods

Comparison Between Generating Method and Form Cutting

Industrial Applications of the Generating Method

3.1 Wind Power Gearboxes

• Requirements: High torque, long service life (≥20 years).
• Process Combination: Hobbing (rough machining) → Heat treatment → Gear grinding (finishing).
Pub Time : 2025-11-20 09:52:14 >> News list