Early Entry cocnrete Blade for Soff Cut Sawing
Early Entry cocnrete Blade for Soff Cut Sawing
The Soff Cut Blades are laser welded concrete blades developed for early-entry cutting of green concrete using Soff cut saw machines. This Early Entry concrete blade is intended for contractors, distributors, and OEM buyers who require clean joint cutting shortly after concrete placement while maintaining controlled crack formation.
- Diameter : 150mm / 200mm / 250mm / 300mm / 343mm / 350mm
- Segment type : Rectangle shape
- Manufacturing Method: Laser welded
- Machine Compatibility: Soff cut saw machine
- Bore Size: Triangle Shape
Product Overview
These blades are designed specifically for early-entry sawing of freshly placed concrete, typically within the first hours after finishing. The segment and bond configuration is developed to allow fast penetration into green concrete while maintaining a clean and controlled kerf for joint formation.
Manufactured using a laser welded process, the Soff Cut Blades are suitable for floor slabs, industrial pads, pavements, and other applications requiring precise contraction joint cutting. Multiple bond types and diamond matrix options are available to match different aggregate hardness conditions encountered on various jobsites.
Specification Data
| Diameter | Inch Diameter | Seg Number | Segment Size |
|---|---|---|---|
| 150mm | 6 inch | 12 | 2.4x10x32 |
| 200mm | 8 inch | 14 | 2.5x10x38 |
| 250mm | 10 inch | 17 | 2.5x10x38 |
| 300mm | 12 inch | 21 | 3.2x10x40 |
| 343mm | 13.5 inch | 23 | 3.2x10x40 |
| 350mm | 14 inch | 24 | 3.2x10x40 |
Key Features
- Designed for early-entry cutting to enable joint sawing in green concrete shortly after finishing
- Specialized diamond matrix supports fast penetration while maintaining a clean and controlled joint line
- Laser welded segment attachment ensures reliable performance during high-speed early-entry operations
- Multiple bond and matrix options allow adaptation to different aggregate hardness conditions
- Stable cutting behavior helps reduce the risk of uncontrolled cracking at joint locations
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