IMPROVING THE RELIABILITY OF COMPRESSOR EQUIPMENT FOR AIR SEPARATION UNITS

Air separation is a process of separating primary components from the atmospheric air. Development of membrane technologies plays a key role in air separation. Multi-layer polymeric nanocomposite membranes have been developed by a novel technique using Polyacrylonitrile (PAN) and cellulose acetate (CA) along with nano silica particles (SiO2) to obtain a higher oxygen selectivity and permeability. For the construction of the multilayer membrane, the Box-Behnken design has been used by employing three independent variables namely PAN Electro spinning time, the SiO2 percentage in the PAN polymer and CA/PEG polymer concentration. The developed membranes have been characterized for its surface morphology and physical properties. Along with the analysis of compound desirability, the results were also subject to statistical analysis in order to form regression equations. The electro spun fiber diameter increases along with the concentration of SiO2 nanoparticles and the range is from 50 nm to 400 nm. Moreover, the maximum pore size on the surface of the membrane lies between 200 to 400 nm whereas the maximum percentage of oxygen purity obtained is 48 with the permeate flux of 5.45 cm3/cm2/min.

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'Evaluation of Cycle Performance in the Direct-Fired S-Co2 Cycle Integrating the Air Separation Unit (Asu) System

SSRN Electronic Journal ◽

10.2139/ssrn.3365879 ◽

2019 ◽

Author(s):

Jin Young Heo ◽

Jeong Ik Lee ◽

Seungjoon Baik ◽

Aqil Jamal ◽

Dokyu Kim

Keyword(s):

Air Separation ◽

Cycle Performance ◽

Separation Unit ◽

Air Separation Unit

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Enhanced oxygen recovery and energy efficiency in a reconfigured single column air separation unit producing pure and impure oxygen simultaneously

Chemical Engineering and Processing - Process Intensification ◽

10.1016/j.cep.2021.108354 ◽

2021 ◽

Vol 162 ◽

pp. 108354

Author(s):

Rohit Singla ◽

Kanchan Chowdhury

Keyword(s):

Energy Efficiency ◽

Air Separation ◽

Separation Unit ◽

Single Column ◽

Air Separation Unit

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CFD-based structure optimization of plate bundle in plate-fin heat exchanger considering flow and heat transfer performance

International Journal of Chemical Reactor Engineering ◽

10.1515/ijcre-2020-0219 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Yao Li ◽

Haiqing Si ◽

Jingxuan Qiu ◽

Yingying Shen ◽

Peihong Zhang ◽

...

Keyword(s):

Heat Transfer ◽

Mass Transfer ◽

Heat Exchanger ◽

Heat And Mass Transfer ◽

Field Performance ◽

High Specific Surface Area ◽

Calculation Model ◽

Air Separation ◽

Transfer Efficiency ◽

Heat Transfer Efficiency

Abstract The plate-fin heat exchanger has been widely applied in the field of air separation and aerospace due to its high specific surface area of heat transfer. However, the low heat transfer efficiency of its plate bundles has also attracted more attention. It is of great significance to optimize the structure of plate-fin heat exchanger to improve its heat transfer efficiency. The plate bundle was studied by combining numerical simulation with experiment. Firstly, according to the heat and mass transfer theory, the plate bundle calculation model of plate-fin heat exchanger was established, and the accuracy of the UDF (User-Defined Functions) for describing the mass and heat transfer was verified. Then, the influences of fin structure parameters on the heat and mass transfer characteristics of channel were discussed, including the height, spacing, thickness and length of fins. Finally the influence of various factors on the flow field performance under different flow states was integrated to complete the optimal design of the plate bundle.

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ASU Simulation in Separating Air Components by Refrigeration Distillation (Oxygen and Nitrogen) Using ASPEN HYSYS (Case Study: SIAD Company)

Chemical Product and Process Modeling ◽

10.1515/cppm-2019-0085 ◽

2020 ◽

Vol 15 (3) ◽

Author(s):

Afshar Alihosseini

Keyword(s):

Cooling Capacity ◽

Air Separation ◽

Cooling Power ◽

Distillation Tower ◽

Aspen Hysys ◽

Expansion Turbine ◽

Gas Products ◽

Utility Services ◽

Petrochemical Industries

AbstractCurrently, air separation units (ASUs) have become very important in various industries, particularly oil and petrochemical industries which provide feed and utility services (oxygen, nitrogen, etc.). In this study, a new industrial ASU was evaluated by collecting operational and process information needed by the simulator by means of HYSYS software (ASPEN-ONE). The results obtained from this simulator were analyzed by ASU data and its error rate was calculated. In this research, the simulation of ASU performance was done in the presence of an expansion turbine in order to provide pressure inside the air distillation tower. Likewise, the cooling capacity of the cooling compartment and the data were analysed. The results indicated that expansion turbine is costly effective. Notably, it not only reduces the energy needed to compress air and supply power of the equipment, but also provides more cooling power and reduces air temperature. Moreover, turbines also increase the concentration of lighter gas products, namely nitrogen.

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Power-to-Green Methanol via CO2 Hydrogenation—A Concept Study Including Oxyfuel Fluidized Bed Combustion of Biomass

Energies ◽

10.3390/en14154638 ◽

2021 ◽

Vol 14 (15) ◽

pp. 4638

Author(s):

Simon Pratschner ◽

Pavel Skopec ◽

Jan Hrdlicka ◽

Franz Winter

Keyword(s):

Large Scale ◽

Positive Impact ◽

Renewable Energy Sources ◽

Air Separation ◽

Model Parameters ◽

Processing Unit ◽

Fluidized Bed Combustion ◽

Separation Unit ◽

Oxyfuel Combustion ◽

Wind Park

A revolution of the global energy industry is without an alternative to solving the climate crisis. However, renewable energy sources typically show significant seasonal and daily fluctuations. This paper provides a system concept model of a decentralized power-to-green methanol plant consisting of a biomass heating plant with a thermal input of 20 MWth. (oxyfuel or air mode), a CO2 processing unit (DeOxo reactor or MEA absorption), an alkaline electrolyzer, a methanol synthesis unit, an air separation unit and a wind park. Applying oxyfuel combustion has the potential to directly utilize O2 generated by the electrolyzer, which was analyzed by varying critical model parameters. A major objective was to determine whether applying oxyfuel combustion has a positive impact on the plant’s power-to-liquid (PtL) efficiency rate. For cases utilizing more than 70% of CO2 generated by the combustion, the oxyfuel’s O2 demand is fully covered by the electrolyzer, making oxyfuel a viable option for large scale applications. Conventional air combustion is recommended for small wind parks and scenarios using surplus electricity. Maximum PtL efficiencies of ηPtL,Oxy = 51.91% and ηPtL,Air = 54.21% can be realized. Additionally, a case study for one year of operation has been conducted yielding an annual output of about 17,000 t/a methanol and 100 GWhth./a thermal energy for an input of 50,500 t/a woodchips and a wind park size of 36 MWp.

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