Ceramic Fiber Blanket Silica and alumina are melted into fibers at high temperatures and applied with pressure to create Ceramic Fiber blankets of various thickness and density levels.
That ceramic fiber blanket makes it ideal for use in environments where the presence of shot is undesirable. The low shot content results in a product with extremely low thermal conductivity.
STA ceramic fiber blanket have these outstanding characteristics:
• Excellent thermal stability and thermal shock resistance
• Excellent chemical stability
• Excellent tensile strength
• Low thermal conductivity
• Low heat storage
• High heat reflectance
• Excellent corrosion resistance
• Excellent hot strength
STA fiber blanket Classification :
STA fiber blanket | CT | RD | TC | TC | chemistry (%) | chemistry (%) | chemistry (%) |
STA-BLANKET 126 | 1260 | 128 | 0,18 | 0,28 | 45 | 55 | - |
STA-BLANKET 143 | 1430 | 128 | 0,19 | 0,27 | 30 | 54 | 16 |
STA-BLANKET 160 | 1600 | 100 | 0,18 | 0,25 | 72 | 28 - |
Ceramic Fiber Blanket Silica and alumina are melted into fibers at high temperatures and applied with pressure to create Ceramic Fiber blankets of various thickness and density levels.
That ceramic fiber blanket makes it ideal for use in environments where the presence of shot is undesirable. The low shot content results in a product with extremely low thermal conductivity.
STA ceramic fiber blanket have these outstanding characteristics:
• Excellent thermal stability and thermal shock resistance
• Excellent chemical stability
• Excellent tensile strength
• Low thermal conductivity
• Low heat storage
• High heat reflectance
• Excellent corrosion resistance
• Excellent hot strength
STA fiber blanket Classification :
STA fiber blanket | CT | RD | TC | TC | chemistry (%) | chemistry (%) | chemistry (%) |
STA-BLANKET 126 | 1260 | 128 | 0,18 | 0,28 | 45 | 55 | - |
STA-BLANKET 143 | 1430 | 128 | 0,19 | 0,27 | 30 | 54 | 16 |
STA-BLANKET 160 | 1600 | 100 | 0,18 | 0,25 | 72 | 28 - |
