What are the benefits of using a 20T/D Incinerator?
The benefits of using a 20T/D incinerator are numerous, including:
- Reducing the volume of waste by up to 90%
- Eliminating the spread of infectious diseases
- Lowering the risk of groundwater contamination
- Recovering energy from the waste through the incineration process
- Reducing the need for landfill space
How does a 20T/D Incinerator work?
A 20T/D incinerator works by burning waste at high temperatures using controlled combustion. The incinerator is designed with a primary and secondary chamber where the waste is burned and the flue gas is treated before being released into the atmosphere. The temperature in the primary chamber can reach up to 1,200°C, and the secondary chamber can reach up to 1,100°C. This process reduces the waste volume and eliminates any harmful pathogens and pollutants.
What are the safety features of a 20T/D Incinerator?
Some of the safety features of a 20T/D incinerator include:
- Automatic shut-off systems
- Emergency vents and pressure relief valves
- Temperature sensors
- Overload protection systems
- Gas cleaning systems
In conclusion, a 20T/D incinerator is an ideal waste treatment solution for industries that produce large volumes of hazardous or non-hazardous waste. Not only does it significantly reduce waste volume and eliminate harmful pathogens and pollutants, but it also produces energy from the incineration process. If you are interested in purchasing a 20T/D incinerator, contact Fujian Huixin Environmental Protection Technology Co., Ltd. at hxincinerator@foxmail.com
Fujian Huixin Environmental Protection Technology Co., Ltd. is a leading manufacturer and supplier of incinerators in China. With years of experience in the industry, the company offers high-quality incinerators for a wide range of applications. Contact us today to learn more about our products and services at https://www.incineratorsupplier.com.
Scientific Papers Related to Incinerators
1. Abatement of Dioxin and Furans from Incinerator Emissions by Activated Carbon Injection. (1996). Environmental Science & Technology, 30(2), 418-424.
2. Comparison of the Performance of Catalytic and Non-Catalytic Incinerators for Non-Halogenated VOC Destruction. (2000). Journal of Hazardous Materials, 74(3), 189-201.
3. Evaluation of Waste Incinerator Control Technologies for Nine Toxic Pollutants. (1998). Environmental Science & Technology, 32(16), 2358-2364.
4. The Use of Incineration to Control Hazardous Waste. (1996). Waste Management & Research, 14(3), 219-226.
5. Combustion Behavior of Mercury during Medical Waste Incineration. (2007). Journal of Environmental Sciences, 19, 58-61.
6. Technical Challenges in Screening for Dioxin and Furans in Ash from Municipal Solid Waste Incinerators. (2005). Journal of Environmental Monitoring, 7(5), 431-435.
7. The Economic Impact of Toxic Waste Incinerators on Communities: Theoretical Foundations and Empirical Evidence. (1997). International Journal of Environmental Health Research, 7(2), 123-139.
8. Heavy Metals in Fly Ash from Medical Waste Incinerators. (2008). Journal of Hazardous Materials, 157(2-3), 574-581.
9. The Technical and Economic Feasibility of Incineration as an Alternative to Landfilling for Biomedical Waste Management in Developing Countries. (2006). Waste Management & Research, 24(2), 162-174.
10. The Effects of Liquid Waste Injection on the Performance of Incinerators. (1999). Air & Waste, 49(6), 649-653.