Product Description
SALES (804) 318-3686
316L STAINLESS STEEL V SPATULA 250 mm
The V Spatula is ideal for surface sampling of powders and core sampling of
semi-solid materials like cheese, pastes and gels.
The ‘V’ shape allows easy discharge of the powders into containers or bags.
Description V-Spatula 250mm x 20mm
Method of Construction: Crevice free, all welds ground and polished
Materials: 316L stainless steel
Surface Finish: Better than 0.5 microns Ra
Overall Length: 333mm
Blade Length: 250mm
Maximum Blade Width: 20mm
Nominal Weight: 185g
Recommended Storage Conditions: Dry and ambient temperature
The V Spatula 316L Stainless Steel 250 mm is a precision tool engineered for efficient sampling in lab environments, particularly suited for powder and semi-solid substances. Its innovative design enhances usability during the delicate process of surface and core sampling, making it a must-have for quality assurance and quality control in pharmaceutical and industrial applications.
Manufactured from high-quality 316L stainless steel, the V Spatula guarantees durability and resistance to corrosion. Its crevice-free construction ensures optimal hygienic standards, which is critical in laboratories that demand stringent compliance with health and safety regulations. The spatula's unique 'V' shape facilitates effortless discharge of materials, preventing contamination and loss of samples.
- Material: 316L stainless steel for superior corrosion resistance
- Crevice-free design with all welds ground and polished for hygiene
- Outstanding surface finish: Better than 0.5 microns Ra for superior cleanliness
- Overall length of 333mm with a blade length of 250mm for versatile sampling
- Maximum blade width of 20mm suitable for a variety of applications
- Lightweight design at 185g for ease of handling and precision
- Recommended storage in dry, ambient conditions to maintain quality
Elevate your laboratory's sampling accuracy with the V Spatula 316L Stainless Steel 250 mm, the reliable choice for professionals committed to excellence in QAQC processes.
