Sintered mesh is generally constructed from multiple layers of stainless steel woven mesh after special laminate pressing and vacuum sintering. It is a new type filter material with higher mechanical strength and overall rigidity, and can be fabricated into filter elements in various shapes, such as round, cylindrical, conical, and pleated shapes. Sintered mesh has uniform pores and not easy to deform, thus delivering a stable filter rating and easy to clean property. As a result, it is widely used in the filtration of chemical, petroleum, pharmaceutical industries, etc.
In addition, we can offer sintered mesh made of Hastelloy, Monel and other alloys to meet the needs of different customers.
A standard and the most widely used sintered mesh. It is a combination of 5 layers of wire mesh with different openings and mesh counts after laminating and vacuum sintering. We can also offer 6-layer sintered mesh that adds a 8-mesh or a 12-mesh square weave mesh on the 5-layer sintered mesh to offer higher mechanical strength and compression strength.
It is made of multiple layers of square plain weave wire mesh after sintering. Square weave wire mesh has square hole opening and high open area rate, so this sintered mesh has excellent permeability, low resistance, high flow rate, etc. It is widely used in powder handling, drying and cooling and other fields with functional requirements, for example, acting as sintered mesh candle filter in chemical filtration applications.
It is constructed of two or three layers of plain Dutch weave wire mesh after laminating and sintering. It has uniform opening distribution and stable permeability and is widely used in fluidized bed, powder handling, air drying, cooling, etc.
It is fabricated by sintering multiple layers of square weave mesh (or Dutch weave mesh) and stainless steel perforated metal (round or square pattern) together. As a result, it combines the good permeability of woven mesh and the excellent mechanical strength of perforated mesh. In addition, it has great backwashing effect and low pressure lose and is widely used in mining, pharmaceuticals, grain screening, etc.
Nominal Filter Rating (μm) | Protection Layer | Filtration Layer | Separation Layer | Reinforcing Layer | Reinforcing Layer | Air Permeability (L/min/cm2) | Bubble Point Pressure (Pa) | Porosity (%) |
---|---|---|---|---|---|---|---|---|
1 | 100 | 400 × 3000 | 100 | 12 × 64 | 64 × 12 | 1.81 | 360–600 | About 40% |
2 | 100 | 325 × 2300 | 100 | 12 × 64 | 64 × 12 | 2.35 | 300–590 | |
5 | 100 | 200 × 1400 | 100 | 12 × 64 | 64 × 12 | 2.42 | 260–550 | |
10 | 100 | 165 × 1400 | 100 | 12 × 64 | 64 × 12 | 3 | 220–500 | |
15 | 100 | 165 × 1200 | 100 | 12 × 64 | 64 × 12 | 3.41 | 200–480 | |
20 | 100 | 165 × 800 | 100 | 12 × 64 | 64 × 12 | 4.5 | 170–450 | |
25 | 100 | 165 × 600 | 100 | 12 × 64 | 64 × 12 | 6.12 | 150–410 | |
30 | 100 | 400 | 100 | 12 × 64 | 64 × 12 | 6.86 | 120–390 | |
40 | 100 | 325 | 100 | 12 × 64 | 64 × 12 | 7.1 | 100–350 | |
50 | 100 | 250 | 100 | 12 × 64 | 64× 12 | 8.41 | 90–300 | |
75 | 100 | 200 | 100 | 12 × 64 | 64 × 12 | 8.7 | 80–250 | |
100 | 100 | 150 | 100 | 12 × 64 | 64 × 12 | 9.1 | 70–190 | |
Notes
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