The Experts below are selected from a list of 264 Experts worldwide ranked by ideXlab platform
Ni Yingchun - One of the best experts on this subject based on the ideXlab platform.
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purple sweet potato biscuit
2015Co-Authors: Ni YingchunAbstract:The invention relates to a purple sweet potato biscuit. The purple sweet potato biscuit is prepared from below Raw Materials of 90-100kg of flour, 21-16kg of powdered sugar, 20-25kg of palm oil, 0.5-0.9kg of syrup, 0.6-1kg of salt, 0.02-0.04kg of vanillin, 0.03-0.03kg of ethyl maltol, 4-6kg of corn starch, 7-8kg of shortening, 11-13kg of grape powder and 0.8-1.2kg of purple sweet potato chips, and production of the purple sweet potato biscuit is completed through steps of Raw Material Preparation, dough mixing, roll cutting shaping, baking, oil spraying, cooling, filling sandwiching, packaging, inspection and warehousing. The purple sweet potato biscuit is convenient to carry, rich in nutrient and good in taste, and meets requirements of people for biscuits.
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chive soda biscuit
2015Co-Authors: Ni YingchunAbstract:The invention relates to a chive soda biscuit. The chive soda biscuit is composed of the following Raw Materials including 45-55 kg of high gluten flour, 90-110 kg of low gluten flour, 14-19 kg of palm oil, 2-3 kg of yellow cream, 0.3-0.7 kg of Angel yeast, 1.7-2.1 kg of salt, 7-8 kg of onion, 0.7-0.8 kg of yeast extract, 0.1-0.3 kg of monosodium, 0.2-0.4 kg of chicken powder, 0.8-1.2 kg of chicken extract, 0.8-1.2 kg of garlic powder, 0.8-1.2 kg of onion powder and 0.1-0.3 kg of chive oil spice. The chive soda biscuit is produced through the steps of Raw Material Preparation, dough mixing, fermentation, laminating and crisping, rolling, roll cutting, baking, oil spraying, dough cooling, packaging, inspection and storage. The chive soda biscuit is convenient to carry, rich in nutrition, good in taste and capable of meeting the requirements of people on biscuits.
Tang Gao-q - One of the best experts on this subject based on the ideXlab platform.
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Study on processing technology of purple sweet potato yoghurt
China Dairy Industry, 2015Co-Authors: Tang Gao-qAbstract:With purple sweet potato and milk as the main Raw Material, Preparation ferment fermentation solidified by the new purple sweet potato yogurt. Through single factor experiment and response surface experiments optimum production purple sweet potato recipe solidified yogurt. Solidifying best purple sweet potato yogurt production process is: purple sweet potato pulp dosage of 6.84%; purple mashed potatoes dosage of 0; white sugar dosage 8%; leavening agent dosage 0.1%; fermentation time 4h; fermentation temperature was 43 ℃. Under this condition,made out of purple sweet potato yogurt unique taste, the state's best, and also has nutritional characteristics of purple sweet potato and yogurt.
Haslenda Hashim - One of the best experts on this subject based on the ideXlab platform.
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low carbon measures for cement plant a review
Journal of Cleaner Production, 2015Co-Authors: Siti Aktar Ishak, Haslenda HashimAbstract:Cement manufacturing is an energy and carbon-intensive industry. The cement industry contributes approximately 5% of the global man-made carbon dioxide (CO2) emissions and is thus becoming the second largest CO2 contributor in industry after power plants. A wide range of options are available to considerably reduce CO2 emissions. This paper reviewed major point sources of CO2 emissions at all stages of cement manufacturing, including (1) Raw Material Preparation (grinding and transportation), (2) clinker production and the combustion of fuels in the kiln and (3) the production of cement final product (milling, blending, mixing, packaging and transportation. Various CO2 mitigation strategies are subsequently discussed, including (1) energy efficiency improvements; (2) waste heat recovery; (3) the substitution of fossil fuel with renewable energy; (4) the production of low carbon cement by replacing ordinary Portland cement with alternative Materials, i.e., geo-polymers, blast furnace slag, coal fly ash, and natural pozzolanic Materials; and (5) carbon capture and storage. Although reviewed CO2 mitigation measures are indeed beneficial to the environment, however, they are also bounded by some limitations. The limitations and selection of CO2 mitigation measure are also outlined in this paper.
Siti Aktar Ishak - One of the best experts on this subject based on the ideXlab platform.
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low carbon measures for cement plant a review
Journal of Cleaner Production, 2015Co-Authors: Siti Aktar Ishak, Haslenda HashimAbstract:Cement manufacturing is an energy and carbon-intensive industry. The cement industry contributes approximately 5% of the global man-made carbon dioxide (CO2) emissions and is thus becoming the second largest CO2 contributor in industry after power plants. A wide range of options are available to considerably reduce CO2 emissions. This paper reviewed major point sources of CO2 emissions at all stages of cement manufacturing, including (1) Raw Material Preparation (grinding and transportation), (2) clinker production and the combustion of fuels in the kiln and (3) the production of cement final product (milling, blending, mixing, packaging and transportation. Various CO2 mitigation strategies are subsequently discussed, including (1) energy efficiency improvements; (2) waste heat recovery; (3) the substitution of fossil fuel with renewable energy; (4) the production of low carbon cement by replacing ordinary Portland cement with alternative Materials, i.e., geo-polymers, blast furnace slag, coal fly ash, and natural pozzolanic Materials; and (5) carbon capture and storage. Although reviewed CO2 mitigation measures are indeed beneficial to the environment, however, they are also bounded by some limitations. The limitations and selection of CO2 mitigation measure are also outlined in this paper.
Shushen Zhang - One of the best experts on this subject based on the ideXlab platform.
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exergetic life cycle assessment of cement production process with waste heat power generation
Energy Conversion and Management, 2014Co-Authors: Yun Zhang, Shuai Shao, Shushen ZhangAbstract:Abstract The cement industry is an industry that consumes a considerable quantity of resources and energy and has a very large influence on the efficient use of global resources and energy. In this study, exergetic life cycle assessment is performed for the cement production process, and the energy efficiency and exergy efficiency of each system before and after waste heat power generation is investigated. The study indicates that, before carrying out a waste heat power generation project, the objective energy efficiencies of the Raw Material Preparation system, pulverized coal Preparation system and rotary kiln system are 39.4%, 10.8% and 50.2%, respectively, and the objective exergy efficiencies are 4.5%, 1.4% and 33.7%, respectively; after carrying out a waste heat power generation project, the objective energy efficiencies are 45.8%, 15.5% and 55.1%, respectively, and the objective exergy efficiencies are 7.8%, 2.8% and 38.1%, respectively. The waste heat power generation project can recover 3.7% of the total input exergy of a rotary kiln system and improve the objective exergy efficiencies of the above three systems. The study can identify degree of resource and energy utilization and the energy-saving effect of a waste heat power generation project on each system, and provide technical support for managers in the implementation of energy-saving schemes.
