STRUCTURAL ASSESSMENT AND REDISIGN OF THE WATER CHAMBER IN A DOMESTIC GASIFICATION BOILER

Proceedings of 41st Danubia-Adria Symposium Advances in Experimental Mechanics (pp. 127-130)

AUTOR(I) / AUTHOR(S): Filip Nastić , Mladen Josijević , Davor Končalović , Dušan Gordić , Vladimir Vukašinović

UVOD / INTRODUCTION:

Residential heating boilers burn fuels to heat water, which flows through a network of pipes and radiators to warm the house. One type of residential heating boiler characterized by its high efficiency is the gasification boiler. Gasification boilers operate with an efficiency of around 85% compared to a classic wood boiler with an efficiency of around 63%. The gasification boilers use a controlled amount of oxygen and precisely defined temperatures to transform the solid biomass into gas, which is later combusted to generate the needed heat. The technology behind gasification boilers is called biomass gasification – a thermochemical conversion of organic feedstock under hightemperature conditions, through which biomass is converted to syngas. Syngas composition varies, but it is mainly composed of CO, H2, N2, CO2, and some hydrocarbons (CH4, C2H4, C2H6, etc.).

A variety of papers have investigated gasification boilers and attempted to optimize their operation and design. The IEA Bioenergy annual report analyzed the product spectrum (organics, char, gas, water) from fast pyrolysis of aspen poplar wood, depending on process temperature. It was shown that with an increase in temperature, the yield of gas also increases. Similar research was done by Raibhole and Sapali, namely, they investigated how the flow rate of oxygen influenced the syngas composition. They concluded that the optimal mass flow of oxygen is around 8 kilograms per hour, when the participation of H2 in syngas is the highest. Karmarković et al. investigated the combustion chamber of the gasification boiler to find its optimal design. Drosatos et al. described the computational fluid dynamics simulation of syngas combustion and the heat transfer in a domestic wood gasification boiler to further optimize its operation. Hopan et al. investigated emissions from 111 measurements on solid fuel household boilers, among which was a hefty number of gasification boilers. One of the conclusions was that emissions-wise, a significant improvement was observed when the gasification boiler was operated by a trained operator.

Overall, regardless of the type of boiler, the heated water is kept in the boiler water wall, hereinafter referred to as the “water chamber” (Fig. 1). To the authors’ knowledge, the pressure of 3 bars is considered as critical pressure of the water in the water chamber, which triggers the activation of the safety valve. This paper investigates how the critical pressure of the water of 3 bars will influence the water chamber with a wall thickness of 5 millimeters, and the possibility of mitigating the displacements without increasing the thickness of the wall.

KLJUČNE REČI / KEYWORDS:

PROJEKAT / ACKNOWLEDGEMENT:

LITERATURA / REFERENCES:

acwholesalers. https://www.acwholesalers.com/Weil-McLain-381359305/p175679.html. Accessed August 27, 2025.
Alternate Heating. Wood Gasification as Next- Generation Wood Burning Technology. https://alternateheatingsystems.com/resources/blog/wood-gasification-as-next-generation-woodburning- technology/. Accessed August 28, 2025.
Biomass Magazine. EPA Lists Efficiencies of Qualified Outdoor Boilers. https://biomassmagazine.com/articles/epa-listsefficiencies- of-qualified-outdoor-boilers-10263. Accessed August 28, 2025.
Green Power. What is a “real pyrolysis boiler”. https://greenpower.equipment/articles/what-is-areal- pyrolysis-boiler/. Accessed August 28, 2025.
Zhang, Y., Cui, Y., Chen, P., Liu, S., Zhou, N., Ding, K., et al. Gasification Technologies and Their Energy Potentials. Sustainable Resource Recovery and Zero Waste Approaches, 2019, 193–206. https://doi.org/10.1016/B978-0-444- 64200-4.00014-1
IEA Bioenergy Annual report 2006. https://www.ieabioenergy.com/wpcontent/ uploads/2013/10/IEA-Bioenergy-2006- Annual-Report.pdf. Accessed August 28, 2025.
Raibhole, V.N. & Sapali, S.N. Simulation of biomass gasification with oxygen/air as gasifying agent by ASPEN plus. Advanced Materials Research, 2013, 622-623:633–8. https://doi.org/10.4028/WWW.SCIENTIFIC.N ET/AMR.622-623.633.
Karmarković, R., Novčić, Đ., Nikolić, M., Karamarković, M., Šimunović, D. Eksperimentalno ispitivanje gasifikacionog kotla: dizajn komore za sagorevanje. Procesna Tehnika, 2018, 30, 1, 20–26. https://doi.org/10.24094/PTC.018.30.1.20 .
Drosatos, P., Nesiadis, A., Nikolopoulos, N., Margaritis, N., Grammelis, P., Kakaras, E. CFD Simulation of Domestic Gasification Boiler. Journal of Energy Engineering 2016, 143, 2. https://doi.org/10.1061/(ASCE)EY.1943- 7897.0000406.
Hopan, F., Chmelář, M., Kremer, J., Dej, M., Vojtíšek-Lom, M., Vicente, ED., et al. In-situ investigation of real-world emissions from 111 measurements on solid fuel household boilers. Science of The Total Environment, 2025, 981.
https://doi.org/10.1016/J.SCITOTENV.2025.179564.
Alternate Heating Systems. https://b2396119.smushcdn.com/2396119/ wp-content/uploads/2019/10/small-WG-notop- feed.png? ossy=2&strip=1&webp=1. Accessed August 28, 2025.
Mohamad, M. L., Rahman, M. T. A., Khan, S. F., Basha, M. H., Adom, A. H., Hashim, M. S.M. Design and static structural analysis of a race car chassis for Formula Society of Automotive Engineers (FSAE) event. Journal of Physics:
Conference Series, 2017. https://doi.org/10.1088/1742-6596/908/1/012042.
Pinca-Bretotean, C. & Chețe, G. Static Analysis Of A Rolling Chassis Using Catia V5, International Journal of Engineering, 2012, ISSN 1584-2673.
Anggono, A. D., Riyadi, T. W. B. Finite element analysis of truck frame by using CATIA V5. AIP Conference Proceedings, 2018, 1977. https://doi.org/10.1063/1.5042949.
Hernandes, J. A., Ferreira, R. T. L., De Faria, A. R., Meleiro, R.M. An assessment of structural optimization using Catia V5. SAE Technical
Papers, 2008. https://doi.org/10.4271/2008-36-0183.