        TY  - JOUR
T1  - Effect of a Heat Exchanger on Syngas Quality and System Efficiency in Biomass Gasification Systems
TT  - Effect of a Heat Exchanger on Syngas Quality and System Efficiency in Biomass Gasification Systems
AU  - Usiohen, Iziegbe
PY  - 2026
DA  - June
Y2  - 2026
DO  - 10.53525/jster.1945708
JF  - Journal of Science, Technology and Engineering Research
JO  - Journal of Science, Technology and Engineering Research
PB  - Mehmet BULUT
WT  - DergiPark
SN  - 2717-8404
IS  - 1
LA  - en
AB  - Downdraft gasifiers are pivotal in biomass gasification, converting organic materials into syngas for use as gaseous fuels and chemical feedstocks. The performance of these systems is heavily influenced by operating conditions. Since the gasification process yields high-temperature products, integrating a heat exchanger allows for the recovery of this thermal energy. This setup preheats the gasifying agent while simultaneously cooling the syngas, which facilitates easier downstream purification and eliminates the need for external heating. In this research, a counter-flow heat exchanger was fitted to the air inlet of a downdraft gasifier. This configuration extracted heat from the hot syngas to preheat the incoming air. Experiments were conducted across an equivalence ratio (ER) range of 0.15 to 0.5. With the heat exchanger, the air temperature was successfully raised from ambient levels (28.3°C–29°C) to between 60.8°C and 77°C. The results demonstrated that the concentrations of combustible gases—carbon monoxide (CO), hydrogen (H₂), and methane (CH₄)—peaked at an ER of 0.3 for both preheated and non-preheated cases. However, preheating yielded superior gas quality. At the optimal ER of 0.3, the preheated setup produced 26.75% CO, 16.24% H₂, and 2.76% CH₄. Without the heat exchanger, these values were lower: 26.30% CO, 13.39% H₂, and 2.15% CH₄. Furthermore, the lower heating value (LHV) and cold gas efficiency (CGE) showed marked improvement with preheating. The maximum LHV reached 5.1825 MJ/kg with a CGE of 64.53%, compared to 4.9435 MJ/kg and 61.56% in the ambient air setup. The study concludes that preheating the gasifying agent significantly enhances syngas quality and overall system efficiency.
KW  - 	Heat Exchanger
KW  - 	Heating Value
KW  - 	Equivalence Ratio
KW  - 	Gasification
KW  - 	Wood Chips
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UR  - https://doi.org/10.53525/jster.1945708
L1  - https://dergipark.org.tr/tr/download/article-file/5986267
ER  -