What question did this study set out to answer?

The central aim is to analyze how excess air ratio affects combustion characteristics and emissions in a CFB boiler.

April 17, 2026Open Access

Numerical investigation of oil shale combustion characteristics in a high-low differential velocity CFB boiler using the CPFD model

Key Points

The central aim is to analyze how excess air ratio affects combustion characteristics and emissions in a CFB boiler.
Utilized the computational particle fluid dynamic (CPFD) model for simulations
Investigated a 65 t/h oil shale-fired CFB boiler
Analyzed effects of excess air ratio on furnace temperature, gas composition, and emissions
Excess air ratio of 1.10 enhances particle back-mixing and combustion
Reduced NO and SO2 emissions achieved
Optimal conditions identified with 1.5:1 main/side bed air distribution for lowest emissions

Abstract

This study employs the computational particle fluid dynamic model to simulate a 65 t/h oil shale-fired high-low differential velocity circulating fluidized bed (CFB) boiler. The effects of the excess air ratio on furnace temperature, gas composition, particle residence time, and pollutant emissions were analyzed. Results show that an excess air ratio of 1.10 intensifies particle back-mixing, enhancing combustion while reducing NO and SO2 emissions. The optimal condition combines this ratio with a 1.5:1 main/side bed air distribution, achieving the lowest emissions. This work provides valuable insights for optimizing CFB boiler operation.

Bookmark

View Full Paper

Bookmark

View Full Paper

Numerical investigation of oil shale combustion characteristics in a high-low differential velocity CFB boiler using the CPFD model

Key Points

Abstract

Cite This Study