Lab-scale Simulation of Coal-Nuclear Synergy : Utilization of High Temperature Reactor Excess Heat in Synthesis Gas and Hydrogen-Rich Gas Production

• Autorzy: Adam Smoliński

Warianty tytułu

Badania symulacyjne synergii węglowo-jądrowej : zastosowanie ciepła nadmiarowego z reaktora HTR w procesie zgazowania węgla do gazu syntezowego i gazu bogatego w wodór

• Języki publikacji: EN

Abstrakty

EN

The paper presents the results of the experimental study on simulated application of High Temperature Reactor (HTR) excess heat in the allothermal coal gasification to synthesis gas and hydrogen-rich gas. The effects of application of gasification agents pre-heating was tested in a laboratory scale fixed bed reactor installation. The installation was equipped with a specially designed auxiliary pre-heating system for gasification agents applied (air, oxygen or steam), simulating the utilization of the HTR excess heat. The results of the study proved the feasibility of the utilization of the external excess heat in air and steam coal gasification. (original abstract)

W artykule przedstawiono wyniki badań symulacyjnych zastosowania ciepła nadmiarowego z wysokotemperaturowego reaktora jądrowego (HTR) w procesie allotermicznego zgazowania węgla do gazu syntezowego i gazu bogatego w wodór. Określono wpływ wstępnego przegrzania czynnika zgazowującego na wyniki procesu zgazowania w laboratoryjnej instalacji z reaktorem ze złożem stałym. Instalacja została wyposażona w specjalnie do tego celu zaprojektowany układ wstępnego przegrzania czynnika zgazowującego (powietrze, tlen lub para wodna), symulujący wykorzystanie ciepła nadmiarowego z reaktora HTR. Wyniki badań potwierdziły możliwość wykorzystania zewnętrznego źródła ciepła nadmiarowego w procesie zgazowania węgla powietrzem i para wodną. (abstrakt oryginalny)

Słowa kluczowe

EN

Simulation; Manufacturing technologies; Energy

PL

Symulacja; Technologie wytwarzania; Energia

• Czasopismo: Polityka Energetyczna
• Rocznik: 2015
• Tom: 18
• Numer: z. 1
• Strony: 69--83

Twórcy

autor

Adam Smoliński

• GIG-Central Mining Institute, Katowice

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