Papers by Author: Xian Ce Meng

Abstract: This study attempted to estimate the environmental performance of poly (propylene carbonate, PPC) in the whole life cycle. The life cycle is from raw materials, energy acquisition, manufacture, transportation, to the final disposal, sequentially. The environment impacts of these phases are assessed by the method of Life Cycle Assessment (LCA) to identify key aspects of environmental loads involving global warming, non-renewable resource consumption, and acidification effects and so on. Moreover, a comparative study due to manufacturing of PPC in its whole life cycle was taken to reveal which stage would make the most environmental load.

Abstract: LCA method was used to model the life cycle of cement manufacturing with multi-stage combustion and low-NOx Burner technology applied as its low-NOx system. The life cycle is from the coal and raw materials transportation, through the coal and raw meal grinding, to the clinker incineration, and finally the flue gas including NOx to the air atmosphere. The functional unit is 1 tonne clinker. Data for cement produced in MSC and LNB technology is analyzed. The data is collected from the real clinker production situation and the measurement is taken in 12 hours continuously.

Abstract: Aerated concrete is a new type of wall material with beneficial features like light weight, heat insulation, fire prevention and low energy consumption. As a key milestone in wall materials innovation and energy-saving of building system, it has been proven to be an ideal wall material which can replace traditional clay brick through years of application and practice. This study calculated the CO₂ emissions in all the stages of life cycle of aerated concrete production. Compared with clay brick, the life cycle CO₂ intensity of aerated concrete block will be decreased by 67.4% with the same insulation effect. Study on the environmental loads of aerated concrete industry will provide theoretical base for the carry out of energy-saving and emission reduction, the formulation of clean production and the development of recycling economy.

Abstract: LCI study is short for life cycle inventory study. In the situation of more strict regulation limit of 500 mg NOx /m³ a demonstration project to reduce NOx emissions with clinker production capacity of 2000 t/d in Beijing is supported by the 'Five-twelfth' National Science and Technology Support Program of China Science and Technology Department. A selective catalytic reduction denitration (SCR DeNOx) technology is expected to be applied in this project. LCA models the life cycle of cement manufacturing with SCR DeNOx technology applied as its SCR system. The life cycle is from the coal and raw materials transportation, through the coal and raw meal grinding, to the clinker incineration, and finally the flue gas including NOx to the SCR reactor. The functional unit is 1 ton clinker. Data for cement produced in LNB technology as bench mark is analyzed and the SCR scenarios are to show that the SCR reactor can be established because the additional environmental impact is small due to small consumptions of reducing agent and electricity. SCR technology enable the deNOx efficiency much higher with small environmental impact.