Recharge method

The zinc-air system is rechargeable by two methods electrical and mechanical. For the electrical rechargeability method, electricity is applied to the cell to convert the zinc oxide species back to zinc metal (or the zinc metal alloy) and oxygen gas. The reactions involved in recharging the cells are below. 

Recychng (or reuse) refers to the use (or reuse) of materials that would otherwise be disposed of or treated as a waste product. A good example is a rechargeable battery. Wastes that cannot be directly reused may often be recovered on-site through methods such as distillation. When on-site recoveiy or reuse is not feasible due to quality specifications or the inability to perform recoveiy on-site, off-site recoveiy at a permitted commerci recoveiy facihty is often a possibility. Such management techniqiies are considered secondaiy to source reduc tion and should only oe used when pollution cannot be prevented. 

Heat recover) from exhaust air—If a heat recoveiy system allows an increase in the rate of outside air supply, lAQ will usually be improved. Proper precautions must be taken to ensure that moisture and contaminants from the exhaust air stream are not transferred to the incoming air stream. An innovative way of recovering heat and reducing the dehumidification cost is to use the waste heat to recharge the desiccant wheels that are then used to remove moisture from the supply air. In this method, the energy savings have to be substantial to offset the high cost of the desiccant wheels. 

Prior to the evaluation of Li[Mn2]04 as a rechargeable cathode material, the ideal spinel framework [Mn2]04, (commonly referred to as A — Mn02, after Hunter) was chemically synthesized by acid digestion of Li[Mn2]04 [121]. The formation of A— Mn02 by chemical methods differs from the electrochemical reaction because it dissolves 25 percent of the Mn cations from the original spinel framework ... 

Many studies have been undertaken with a view to improving lithium anode performance to obtain a practical cell. This section will describe recent progress in the study of lithium-metal anodes and the cells. Sections 3.2 to 3.7 describe studies on the surface of uncycled lithium and of lithium coupled with electrolytes, methods for measuring the cycling efficiency of lithium, the morphology of deposited lithium, the mechanism of lithium deposition and dissolution, the amount of dead lithium, the improvement of cycling efficiency, and alternatives to the lithium-metal anode. Section 3.8 describes the safety of rechargeable lithium-metal cells. 

Hence, BSS recharging substantially hinders the adsorption-induced change in degree of barrier disarrangement of adsorbent and in several cases can bring about small sensitivity of electrophysical characteristics of adsorbent to the adsorption process. We should note that above BSS recharging can be one of reasons of notable effect of adsorbent manufacturing prehistory of and the methods to treat its surface on the value and kinetics of chemisorption response. 

The mechanisms and reasons of catalytic activity of polyaniline (PANI)-type conducting polymers toward oxygen reduction in acidic and saline solutions are investigated by electrochemical and quantum-chemical methods. The PANI/thermally expanded graphite compositions were developed for realization of fully functional air gas-diffusion electrodes. Principally new concept for creation of rechargeable metal-air batteries with such type of catalysts is proposed. The mockups of primary and rechargeable metal-air batteries with new type of polymer composite catalysts were developed and tested. 

The recoverability of hydrocarbon from the subsurface refers to the amount of mobile hydrocarbon available. Hydrocarbon that is retained in the unsaturated zone is not typically recoverable by conventional means. Additional amounts of hydrocarbon that are unrecoverable by conventional methods include the immobile hydrocarbons associated with the water table capillary zone. Residual hydrocarbon is pellicular or insular, and is retained in the aquifer matrix. With respect to recoverability, residual hydrocarbon entrapment can result in volume estimate discrepancies as well as decreases in recovery efficiency. With increasing water saturation, such as when the water table rises via recharge or product removal, hydrocarbons essentially become occluded by a continuous water phase. This results in a reduction of LNAPL and product thickness as measured in the well at constant volume. When water saturation is decreased by lowering the water table (as during recovery operations), trapped hydrocarbons can remobilize, leading to increased recoverability. 

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