Research on Kitchen Waste Disposal Equipment and Technology

Feng Qin He; Hua Lin Wang; Peng Qian; Su Ming Xu

doi:10.4028/www.scientific.net/AMR.194-196.2127

Paper Titles

The Microstructure and Properties of Restored WC_P/Fe-C Composites
p.2105

Recycling and Characterisation of Amorphous Silica from Zr-Containing Silica Residue
p.2109

Gallium and Arsenic Recovery from Waste Gallium Arsenide by Wet Refined Methods
p.2115

Hydration Characteristics and Cementious Properties of Pyrolytic Steel Slag
p.2119

Research on Kitchen Waste Disposal Equipment and Technology
p.2127

Effect of Brown Corundum Dust Powder on the Sintering Performance of Corundum-Silicon Nitride Castable
p.2131

The Preparation of High-Strength and Micropore Lightweight Bauxite Aggregate by In Situ Polymerization and Decomposition
p.2135

Mineral Sequestration of CO₂ Using Basic Oxygen Furnace (BOF) Steelmaking Slag
p.2140

Thermodynamic Analysis on Separation Process of Iron and Niobium for Iron Tailings Containing Niobium
p.2145

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 194-196Research on Kitchen Waste Disposal Equipment and...

Research on Kitchen Waste Disposal Equipment and Technology

Abstract:

In this paper, we concluded that, in order to make good experiment effect, kitchen waste temperature rising rate should be at least 20°С / min. Taking in account experiment effect and experiment energy consumption, a pyrolysising technology is designed to change the kitchen waste's temperature rising rate in phases. At last, a set of mechanical equipment is designed to solve kitchen waste problem efficiently as well as produce bio-oil and other chemical raw materials. The result of prototype experiment shows the feasibility of the kitchen waste disposal equipment and technology.

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Periodical:

Advanced Materials Research (Volumes 194-196)

Pages:

2127-2130

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.194-196.2127

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Online since:

February 2011

Authors:

Feng Qin He, Hua Lin Wang, Peng Qian, Su Ming Xu

Keywords:

Equipment, Kitchen Waste, Pyrolysis, Technology

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