D2 610mm Length Industry Round Cutting Blade For Printing Packaging

D2 610mm Length Industry Round Cutting Blade For Printing Packaging

Description:

Here are some specific recommendations for blade geometry design based on common cutting materials and processes:

1,Cutting soft materials (e.g., plastics, rubber, thin metals):

• Choose flat or slightly convex blade edge design
• Tooth pattern can be standard straight or serrated
• Blade material can be high-speed steel or coated high-speed steel

2,Cutting medium-hardness materials (e.g., medium carbon steel, aluminum alloys):

• Choose slightly convex or R-type blade edge design
• Tooth pattern can be helical or wave-like
• Blade material can be tungsten carbide or coated diamond

3,Cutting hard materials (e.g., stainless steel, alloy steels):

• Choose R-type or concave blade edge design
• Tooth pattern is best suited for helical or pyramidal shape
• Blade material should be coated diamond or ceramic

4,Cutting highly ductile materials (e.g., thick metal plates, composite materials):

• Choose saw-tooth or perforated blade edge design
• Tooth pattern can be helical or pyramidal
• Blade material should be coated diamond or ceramic

5,For high-speed cutting processes:

• Select blade materials with good thermal conductivity
• Adopt blade designs with cooling channels at the tip
• Tooth pattern can have a specialized angled geometry to reduce vibration

Industrial Blade Specifications:

When selecting the optimal tooth pattern for your cutting requirements, there are several key factors to consider:

1,Material hardness and toughness:

• Softer materials generally work better with straight or serrated tooth patterns to avoid excessive deformation.
• Harder materials benefit from angled or hooked tooth patterns that can better fracture the material.
• Highly ductile materials may require specialized tooth designs like saw-tooth or pyramidal patterns to prevent material buildup.

2,Cutting speed and feed rate:

• High-speed cutting often performs better with angled or wave-like tooth patterns to reduce vibration and chatter.
• Lower speeds may allow simpler straight-edged teeth, but higher feeds may necessitate more aggressive patterns.

3,Part geometry and accessibility:

• Complex or hard-to-reach workpiece shapes may require specialized tooth designs for effective cutting.
• Internal cuts or tight clearances may favor tooth patterns that can navigate tight spaces.

4,Noise and surface finish requirements:

• Smoother finishes are generally achieved with finer-pitched, more numerous teeth.
• Coarser tooth patterns produce a rougher surface finish but may be preferred for rapid material removal.
• Noise generation during cutting can be minimized by using angled or serrated tooth profiles.

5,Tool life and maintenance:

• More aggressive tooth geometries tend to wear faster and require more frequent resharpening.
• Compromise may be needed between cutting performance and tool longevity.

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