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Difference between revisions of "Bag Filters"
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* Please start editing this page after the /noinclude | * Please start editing this page after the /noinclude | ||
* -------------------------------------------------></noinclude> | * -------------------------------------------------></noinclude> | ||
[[File:Bag_filters_01.jpg|thumb|right|Bag filter]] | [[File:Bag_filters_01.jpg|thumb|right|Bag filter]] | ||
[[File:Bag_filters_02.jpg|thumb|right|Bag filtering system]] | [[File:Bag_filters_02.jpg|thumb|right|Bag filtering system]] | ||
[[File:Bag_filters_03.jpg|thumb|right|Bag filtering model]] | [[File:Bag_filters_03.jpg|thumb|right|Bag filtering model]] | ||
[[File:Bag_filters_04.jpg|thumb|right|Bag filtering system]] | [[File:Bag_filters_04.jpg|thumb|right|Bag filtering system]] | ||
A typical '''bag filter''' has a dimension of 592 mm x 592 mm and consists of 4 to 12 parallel bags. The length and depth of the bag filter varies from 300 mm up to 900 mm. Bag Filter media efficiency varies from very low (coarse filter) to very high (fine filers). The Bag filter material is made of glass or polymer fibers of different thickness or number of layers, depending on the required filter performance. | |||
A typical bag filter has a dimension of 592 mm x 592 mm and consists of 4 to 12 parallel bags. The length and depth of the bag filter varies from 300 mm up to 900 mm. Bag Filter media efficiency varies from very low (coarse filter) to very high (fine filers). The Bag filter material is made of glass or polymer fibers of different thickness or number of layers, depending on the required filter performance. | |||
A prime example of the ways in which hot gas emitting applications can contain highly risky levels of contaminants and pollutants: cremation. The bacteria and possible infections present in a dead body are many, varied and all basically nasty. You can't just burn a corpse and have the smoke wander around unscrubbed. The use of bag filters benefits a crematorium (and anyone who lives anywhere near one) by operating with 100% efficiency as part of a bespoke system, which can remove all harmful particles from the gas flow (i.e. the smoke) before it exits the smoke stack. | A prime example of the ways in which hot gas emitting applications can contain highly risky levels of contaminants and pollutants: cremation. The bacteria and possible infections present in a dead body are many, varied and all basically nasty. You can't just burn a corpse and have the smoke wander around unscrubbed. The use of bag filters benefits a crematorium (and anyone who lives anywhere near one) by operating with 100% efficiency as part of a bespoke system, which can remove all harmful particles from the gas flow (i.e. the smoke) before it exits the smoke stack. | ||
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<b>Metal Working</b> | <b>Metal Working</b> | ||
<i>Applications</i>: Filtration of lubricant oil, circulating filtration of cooling water, precious metal recovery, pretreatment system filtration, Filtration of rust resistance oil ,Filtration of hydraulic oil, Filtraion of ultra precision burn-ishing oil, Oil removal of chip liquid and rinsing liquid, Parts cleaning machines use | <i>Applications</i>: Filtration of lubricant oil, circulating filtration of cooling water, precious metal recovery, pretreatment system filtration, Filtration of rust resistance oil ,Filtration of hydraulic oil, Filtraion of ultra precision burn-ishing oil, Oil removal of chip liquid and rinsing liquid, Parts cleaning machines use filter bags for minimizing residual dirt on parts. | ||
<i>Benefits</i>: Recovery of valuable catalyst, enhance operating efficiency, low operation cost and wastage, maintain the PH value of bio-materials, extend the life of biomaterials, increase the purification degree of products, protect metal processing facilities, lower operating cost, higher processing efficiency, improve the eligible rate of products. | <i>Benefits</i>: Recovery of valuable catalyst, enhance operating efficiency, low operation cost and wastage, maintain the PH value of bio-materials, extend the life of biomaterials, increase the purification degree of products, protect metal processing facilities, lower operating cost, higher processing efficiency, improve the eligible rate of products. | ||
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<i>Benefits</i>: Improving polishing degree and purifying degree of products, Low investment cost and operating cost , improve product quality. | <i>Benefits</i>: Improving polishing degree and purifying degree of products, Low investment cost and operating cost , improve product quality. | ||
==Video== | ==Video== | ||
<youtube>pGFIbKhLuLo</youtube> | <youtube>pGFIbKhLuLo</youtube> | ||