Bag Filter Market by Production, Revenue, Consumption,
Export and Import Forecast till 2020
The report "Bag Filter Market by Type (Pulse jet, Reverse-Air, and Shaker), by Media
(Nonwoven, Woven and Others), by Application (Power Generation, Chemical, Mining,
Cement, Pulp & Paper, Municipal Waste, and Others) & by Region - Global Forecast to
2020" , defines and segments the global bag filter market with an analysis and forecast of the
market size.
Browse 66 market data Tables and 40 Figures spread through 143 Pages and in -depth TOC
on "Bag Filter Market - Global Forecast to 2020"
The bag filter market is expected to grow from an estimated USD 9.13 Billion in 2015 to USD
12.12 Billion by 2020, at a CAGR of 5.8% from 2015 to 2020. Environment & safety regulations of
different governments to reduce particulate emission from various industries along with the
development in cement & mining industry is fueling the growth of the bag filter industry
worldwide.
Pulse Jet to Dominate the Bag Filter Market
Amongst the different types of cleansing actions of bag filters, pulse jet is considered to be the
best alternative when compared to shaker and reverse-air bag filters. It holds the largest market
with major application in pharmaceuticals, food & beverages, sinter plants, textiles, chemicals,
and municipal waste industries, among others.
Nonwoven Media to Capture the Major Share in the Next Five Years
The report also segments the bag filter market on the basis of its media: nonwoven and woven.
Nonwoven fabric is widely used across all end-user applications. Nonwoven media are used in
high-energy cleansing systems while woven ones used in low-energy devices. High energy
systems consist of pulse jet devices whereas low energy system utilizes shakers and reverse -air
flow devices. The report also considered filtering media such as meshes and glass fibers among
others. Nonwoven fabrics are products made of parallel laid, cross laid, or randomly laid webs
bonded with application of adhesive or thermoplastic fibers under application of pressure and
heat.