Natural bamboo charcoal (BC) powder has been developed as a novel filler in order to further improve performances of the polyvinyl alcohol (PVA)-based alkaline solid polymer electrolyte (ASPE) by solution casting method. X-ray diffraction patterns of composite polymer electrolyte with BC revealed the decrease in the degree of crystallinity with increasing content of BC. Scanning electron microscopy images showed pores on a micrometer scale (average diameter about 2 μm) distributed inside and on the surface of the membranes, indicating a three-dimension network formed in the polymer framework. The ionic conductivity was measured by the alternating-current (AC) impedance method, and the highest conductivity value of 6.63 × 10−2 S·cm−1 was obtained with 16 wt % of BC content and mKOH:mPVA = 2:1.5 at 30 °C. The contents of BC and KOH could significantly influence the conductivity. The temperature dependence of the bulk electrical conductivity displayed a combination of Arrhenius nature, and the activation energy for the ion in polymer electrolyte has been calculated. The electrochemical stability window of the electrolyte membrane was over 1.6 V. The thermogravimetric analysis curves showed that the degradation temperatures of PVA-BC-KOH ASPE membranes shifted toward higher with adding BC. A simple nickel-hydrogen battery containing PVA-BC-KOH electrolyte membrane was assembled with a maximum discharge capacity of 193 mAh·g−1.
A process optimization is carried out to separate binary azeotropic mixtures of tetrahydrofuran and methanol by pressure-swing distillation according to the pressure-sensitive property of the binary system. Rigorous steady-state simulation that is based on the minimization of the total annual cost for partially and fully heat-integrated pressure-swing-distillation processes is implemented on Aspen Plus following the sequential iterative optimization procedure. The feasible sequence of high pressure and low pressure of two columns in the pressure-swing-distillation process and the suitable heat integration scheme are both determined by the feed composition.
Liquid CO2 phase transition fracturing (LCPTF)
is a
kind of novel waterless fracturing technology for enhancing the coalbed
methane (CBM) recovery. Relevant current studies are focused on exploring
the transformed effect of LCPTF on the nanopore structure in coal.
However, its influence on gas adsorption capacity has been rarely
reported. This study addresses coal induced with LCPTF. The structure
alterations of mesopores (2–50 nm) and macropores (>50 nm)
and their effects on the gas adsorption capacity are evaluated with
comprehensive measurements of a mercury intrusion porosimetry, low-temperature
N2 adsorption, and isothermal adsorption. The results indicate
that LCPTF has an enlarged effect on macropores, resulting in an increase
in pore size and volume and a reduction of the pore specific surface
area. The pore-enlarged-transformed effects of LCPTF cause an increase
in pore size and a reduction of the pore volume and pore specific
surface area of mesopores. The variations of the pore structure after
LCPTF cause a reduction of the adsorption constant a and the increase in the adsorption constant b,
indicating LCPTF’s reductive effect on adsorption capacity
as well as its enhanced effect on desorption capacity. A novel effect
evaluation method of LCPTF for improving CBM recoverability is proposed
based on the variations of gas saturation and critical desorption
pressure. This study examines, from the perspective of adsorption
and desorption, the mechanism of LCPTF for enhancing CBM recovery,
which provides theoretical guidance for LCPTF’s technical improvement
and optimization of field application so as to secure a more reliable
and efficient CBM recovery.
Friction stir processing (FSP) was used to achieve grain refinement on Mg-Al-Zn alloys, which also brought in significant texture modification. The different micro-texture characteristics were found to cause irregular micro-hardness distribution in FSPed region. The effects of texture and grain size were investigated by comparative analyses with strongly textured rolling sheet. Grain refinement improved both strength and elongation in condition of a basal texture while such led to an increment in yield stress and a drop in elongation and ultimate stress when the basal texture was modified by FSP.
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