A loose nanofiltration (NF) membrane with excellent dye rejection and high permeation of inorganic salt is required to fractionate dye/salt mixture in dye wastewater treatment. In this study, we fabricated the loose NF membrane by using the electrospray interfacial polymerization (EIP) method. It is a novel and facile interfacial polymerization method, which controls the thickness of the poly(piperazine-amide) (PPA) layer in nanometers (1 nm/min) and changes cross-linking degree of PPA layer and pore size by varying the electrospray time; consequently, water permeance and dye/salt rejection ratio can be handled. The fabricated EIP membrane with an optimized fabrication condition (M30, electrospray time was 30 min) possessed excellent pure water permeance (20.2 LMH/bar), high dye rejection (e.g., 99.6% for congo red (CR)), and low salt rejection (e.g., 6.3% for NaCl). Moreover, the EIP membrane exhibited enhanced antifouling property than commercial NF membrane (NF90) with a high flux recovery rate (FRR) of 87.1% and low irreversible fouling (R ir ) of 12.9% after fouled by bovine serum albumin (BSA) due to its great smooth surface (average roughness (R a ) is 12.2 nm), hydrophilicity property, enhanced zeta potential, and low protein adsorption. The results indicate that the EIP loose NF membrane had a high potential for dye wastewater treatment.
Membrane
deformation is a significant problem in osmotically driven
membrane processes, as it restricts practical operating conditions
and reduces overall process performance due to unfavorable alteration
of membrane permeation characteristics. In this respect, a spacer
plays a crucial role, as it dictates the form and extent of membrane
deformation in association with concentration polarization (CP), which
is also influenced by spacer-induced hydrodynamic behavior near the
membrane surface. These two roles of spacers on membrane permeation
characteristics are inherently inseparable with the coexistence of
hydraulic and osmotic pressures. Here, we suggest a novel analytical
method to differentially quantify the proportions of effective osmotic
pressure drop caused by membrane deformation and CP. Furthermore,
we tested two different FO membranes with three different spacer configurations
to define and discuss different forms of membrane deformation and
their effects on membrane permeation characteristics. The differential
analysis revealed the effect of spacer configuration on effective
osmotic pressure drop in membrane deformation (up to ∼201%
of variation) is much greater than that in CP (up to ∼20.1%
of variation). In addition, a combined configuration of a feed spacer
and tricot spacer demonstrated its ability of mitigating membrane
deformation with lower selectivity loss and channel pressure drop
under pressurization.
We report an ultra-low resistance superconducting joint using unreacted multifilament MgB2 wires produced by tailoring the powder compaction pressure within the joint with heat treatment conditions. The joint demonstrated an ultra-low resistance of 5.48 10 -15 and critical current (Ic) of 91.3 A at 20 K in self-field. The microstructural and composition studies of the joint revealed cracks and a high amount of MgO, respectively. These two features reduced the Ic of the joint to some extent; nevertheless, the joint resistance was not affected by it. Our tailored joining process will play a pivotal role in superconducting joint development.
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