| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Ideal-tek |
HP BLADES FOR HNDL N.4-6A1=5 |
16 |
|
 |
Ideal-tek |
BLADE FOR 4313 SM HDL 1=5 |
38 |
|
 |
Ideal-tek |
BLADE FOR KNIP126 100/BOX |
91 |
|
 |
Ideal-tek |
HP BLADES FOR HDL N.4-6A1=5 |
9 |
|
 |
Ideal-tek |
HP BLADES FOR HNDL N.3-5A-71=5 |
40 |
|
 |
Ideal-tek |
BLADE FOR 4307SMOR SM HDL 1=50 |
1 |
|
 |
Ideal-tek |
BLADES FOR ACMH1 SM HDL 1=5 |
43 |
|
 |
Ideal-tek |
HANDLE AND BLADE SET 16/PC |
0 |
|
 |
Ideal-tek |
BLADE FOR 4307SMOR SM HDL 1=50 |
2 |
|
 |
Ideal-tek |
SCRAPER SINGLE EDGE W/BLADES |
24 |
|
 |
Ideal-tek |
PLASTIC HANDLE WITH 311 SM BLADE |
10 |
|
 |
Ideal-tek |
BLADE FOR 4307SMOR SM HDL 1=50 |
2 |
|
 |
Ideal-tek |
HIGH PRECISION SCISSORS - EXTRA |
0 |
|
 |
Ideal-tek |
HP BLADES FOR HNDL N.4-6A1=5 |
28 |
|
 |
Ideal-tek |
SCALPEL HANDLE W/10 BLADES |
4 |
|
 |
Ideal-tek |
HIGH PRECISION SCISSORS - ROUND |
0 |
|
 |
Ideal-tek |
BLADES FOR ACMH5 SM HDL 1=5 |
10 |
|
 |
Ideal-tek |
HP BLADES FOR HNDL N.4-6A1=5 |
32 |
|
 |
Ideal-tek |
BLADES FOR ACMH5 SM HDL 1=5 |
17 |
|
 |
Ideal-tek |
HIGH PRECISION SCISSORS - EXTRA |
0 |
|
Cutting tools are precision instruments designed to cut, slice, or shape materials through controlled force application. This category includes knives, blades, and specialized cutting devices used across industrial, commercial, and consumer sectors. Modern advancements in material science and manufacturing have significantly enhanced their durability, precision, and application-specific performance, making them critical components in fields ranging from surgical operations to aerospace engineering.
| Type | Functional Characteristics | Application Examples |
|---|---|---|
| Utility Knives | Replaceable blades, ergonomic handles, adjustable depth control | Packaging, drywall cutting, general maintenance |
| Industrial Shears | Hydraulic/pneumatic actuation, reinforced blades, high-torque cutting | Steel plate shearing, automotive recycling, metal fabrication |
| Surgical Scalpels | Disposable stainless steel blades, sterile packaging, precise tip geometry | Medical surgeries, pathological tissue sectioning |
| Rotary Cutters | Rotating circular blades, safety guards, adjustable pressure | Textile cutting, vinyl sign making, craft applications |
| Band Saw Blades | Continuous toothed metal bands, variable tooth pitch, heat-resistant coatings | Woodworking, metallography, food processing |
Typical cutting tools feature: - Blade Core: High-carbon steel, tool steel, or ceramic materials with engineered edge geometry - Coatings: Titanium nitride (TiN), diamond-like carbon (DLC) for wear resistance - Handle/Ergonomic Design: Textured polymer grips with vibration dampening - Actuation Mechanism: Manual, electric, or pneumatic systems with force amplification - Safety Features: Blade guards, automatic retraction, non-slip surfaces
| Parameter | Value Range | Importance |
|---|---|---|
| Blade Hardness (HRC) | 45-68 | Determines wear resistance and edge retention |
| Cutting Length | 10-3000mm | Defines operational scale and material capacity |
| Edge Bevel Angle | 15 -40 | Affects cutting efficiency and durability |
| Corrosion Resistance | Ratings: 1-5 (ASTM B117) | Critical for chemical/environmental exposure |
| Operating Temperature | -50 C to 600 C | Material stability under thermal stress |
| Manufacturer | Representative Product | Key Innovation |
|---|---|---|
| Olfa Corporation | KN-500 Rotary Cutter | Auto-retracting safety mechanism |
| Carlisle Foodservice | 4125 Series Utility Knife | Textured grip with blade depth control |
| Sandvik Coromant | CoroCut QD | Double-sided inserts for extended tool life |
| Walter AG | Tiger tec Coated Blades | High-performance coating for metal cutting |
| Intuitive Surgical | da Vinci Surgical System Blades | Robotic-assisted precision cutting |
Key considerations include: - Material compatibility (e.g., stainless steel blades for acidic environments) - Cutting force requirements (manual vs. powered tools) - Safety certifications (ISO 28350 for medical devices) - Maintenance accessibility (blade replacement frequency) - Ergonomic compliance (EN 614-2 standards)
Case Study: Automotive manufacturers prefer pneumatic shears with tungsten carbide blades for recycling operations due to their 30% higher throughput compared to traditional tools.
Emerging developments include: - Integration of smart sensors for real-time wear monitoring - Nanocomposite coatings reducing friction by 40% - Additive manufacturing enabling complex blade geometries - Sustainable blade recycling programs (e.g., Stanley Black & Decker's circular economy initiative) - AI-powered cutting optimization in industrial settings