Characteristics of foam sol clay for controlling coal dust

A foam sol clay (FSC) mixture, mainly composed of fly ash (FA), surfactant (n-amylamine) and polyethylene oxide (PEO), was proposed for coal dust control. The FA surface, modified by a FSC solution, stability and foamability were investigated. It was found that the FA surface in alkaline solution wa...

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Bibliographic Details
Published in:Powder technology 2018-07, Vol.335, p.401-408
Main Authors: Xi, Zhilin, Jin, Liwei, Richard Liew, J.Y., Li, Ding
Format: Article
Language:English
Subjects:
Armor
Chains
Clay
Coal
Coal dust
Contact angle
Contact potentials
Control stability
Drying
Dust
Dust control
Electrostatic properties
Flow resistance
Fly ash
Foam sol clay
Froth stability
Hydrophobicity
Interface stability
Interfaces
Polyethylene
Polyethylene oxide
Polyethylenes
Sodium
Sodium dodecyl sulfate
Sodium lauryl sulfate
Surface stability
Surfactants
Viscosity
Wettability
Zeta potential
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Summary:A foam sol clay (FSC) mixture, mainly composed of fly ash (FA), surfactant (n-amylamine) and polyethylene oxide (PEO), was proposed for coal dust control. The FA surface, modified by a FSC solution, stability and foamability were investigated. It was found that the FA surface in alkaline solution was deprotonated to form a negative charge, which could be adsorbed by the polar head group of n-amylamine via electrostatic interactions. As a result, with increasing surfactant, the particles gradually converted from hydrophilic to hydrophobic and attached at gas-liquid interfaces so that the contact angle, zeta potential, froth stability and foamability increased. At a surfactant concentration (ca) of 35 g/L, a monolayer three-dimensional network was formed and the maximum foamability and half-life were obtained. Upon further increasing ca, a bilayer and particle clusters were formed by surfactant chain-chain interaction, resulting in particles becoming hydrophilic again, and the FSC solution having stronger mechanical resistance against flowing, so that the viscosity rapidly increased and the diffusion of free surfactant molecules was hindered at the froth surfaces. Thus, the contact angle, froth stability and foamability decreased. PEO could bond sodium dodecyl sulfate and water to form a dual adsorption layer and hydrogen, respectively, which enhanced the wettability of the FSC on coal dust surfaces. PEO could adsorb and curl FA particles to form a thin layer of armor after froth air-drying. It was concluded that the froth generated by the FSC solution, including 200 g/L FA, 35 g/L ca and 1 g/L PEO, could control coal dust with a long-term effect. [Display omitted] •Foam sol clay for controlling coal dust was proposed.•Fly ash particles surface modified by n-amylamine was analyzed.•The mechanism of fly ash for froth stability was studied.•The mechanism of polyethylene oxide for froth stability and wetting dust was studied.
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2018.05.037