lab ceramic worktops
There have been dual breakthroughs in the materials and processes of lab ceramic worktops. In terms of materials, the use of nano-scale oxides and special fiber additives has reconstructed the molecular lattice structure, increasing its hardness by 40% and significantly enhancing its resistance to acids and alkalis. Regarding the manufacturing processes, isostatic pressing is combined with microwave sintering technology. This enables rapid densification at a high temperature of 2,000°C, reducing the internal porosity to less than 1%. As a result, the thickness of the countertop slabs has been reduced from 20 mm to 15 mm, while still maintaining high strength and impact resistance. The synergy between material innovation and process reform allows these countertops to meet the challenges of high-intensity and high-corrosion environments in laboratories with their thin and lightweight form.
Chemical resistance
When facing the erosion of chemical reagents, lab ceramic worktops also perform excellently. Whether it is strong oxidizing nitric acid, highly corrosive hydrochloric acid, or various organic solutions, it is difficult for them to cause substantial damage to the workbench. It can effectively resist the corrosion of these chemical substances and always maintain the integrity and stability of the workbench. Moreover, due to its special material composition, it can effectively absorb and reflect ultraviolet rays. Even after long – term exposure to ultraviolet rays, it will not experience aging or discoloration, thus maintaining its excellent physical and chemical properties
heat resistance
Its excellent high temperature resistance is also remarkable. During high temperature experiments, such as metal melting and ceramic firing, lab ceramic worktops can withstand the harsh conditions of high temperature and will not deform or crack due to heating. This not only ensures the smooth progress of experiments but also avoids experimental accidents caused by workbench damage, effectively protecting experimental equipment and personnel safety.
Low maintenance
The microstructure of lab ceramic worktops is nearly perfect. Their surfaces are smooth and flat and have no pores, which makes it difficult for dirt to penetrate and adhere. In daily cleaning work, just wiping gently with a wet cloth can easily remove dust and general dirt on the surface. Even if it encounters relatively stubborn dirt, such as paint accidentally smeared during experiments or dried chemical reagents, wiping with a mild detergent can quickly restore the cleanliness of the workbench. In addition, it does not need complex maintenance procedures such as regular waxing and coating repair like some other material workbenches.