Gazéification du GNL par cycle de Brayton associé à une boucle caloportrice et une pompe à chaleur / Gasification of LNG using a Brayton cycle associated to a heat transfer fluid loop and a heat pump

Hadid, Zoheir

04 October 2012

Le marché du gaz naturel liquéfié (GNL) est en plein essor et présente l'avantage de diversifier les approvisionnements. Le GNL est acheminé à une température de -162 °C et à pression atmosphérique. L'objet principal de la thèse vise à valoriser l'exergie contenue dans le GNL lors de sa gazéification et de son réchauffage avant d'être distribué sur le réseau. La thèse étudie un nouveau concept de gazéification qui se différentie des développements en cours par l'usage de l'air ambiant comme seule source de chaleur et par la valorisation d'une partie de l'exergie du GNL en énergie mécanique.Une analyse énergétique et exergétique a permis de définir des architectures de cycles moteurs utilisant l'énergie calorifique de l'air comme source chaude (récupérée par un fluide intermédiaire qui est le propane) et le GNL comme puits froid.L'usage de l'air ambiant conduit à gérer les cycles de givrage et dégivrage sur les évaporateurs du fluide intermédiaire récupérant les calories de l'air. Ceci nécessite la compréhension des phénomènes couplés de transferts de chaleur et de masse. Pour cela un banc d'essai a été construit afin de caractériser des échangeurs à ailettes rondes discontinues en condition de givrage et de valider un modèle numérique simulant le comportement de ces échangeurs en présence de givre. Cette modélisation a permis de proposer une logique de dimensionnement et d'exploitation des évaporateurs à air en prenant en compte l'effet du givre. Une étude saisonnière a montré que le procédé proposé est énergétiquement excédentaire tout au long de l'année. / The market of liquefied natural gas (LNG) is growing and presents the advantage of diversifying supplies. The LNG is fed at a temperature of -162°C and at atmospheric pressure. The main objective of the thesis aims at the valorization of the LNG exergy during its gasification and heating before being delivered through the network. The thesis investigates a new concept of gasification that differs from the current developments by the use of ambient air as the only heat source and by partial valorization of the LNG exergy in mechanical energy.An energy and exergy analysis helped to the definition of engine-cycle architectures using the air heating capacity as a heat source (recovered by an intermediate fluid, here propane) and LNG as a cold sink.The use of ambient air led to manage frosting and defrosting cycles on the evaporators of intermediate fluid recovering heat from the air. This requires understanding the coupled heat and mass-transfer phenomena. A test bench was built to characterize Circular Finned-Tube Heat Exchangers in frosting conditions and to validate a numerical model simulating the behavior of such heat exchangers in presence of frost. As a result, a logic for the design and operation of air heat exchangers is proposed taking into account the frosting effect. A seasonal study showed that the output power generated by the new concept of gasification is superior to its energy consumption throughout the year.

Re-gazéification

GNL

Cycle Brayton

Pompe à chaleur

Caloporteur

Re-gaseification

LNG

Brayton cycle

Heat pump

Heat transfer fluid

Avaliação do funcionamento de motor ice com gas de baixo poder calorifico proveniente da gaseificação de casca de arroz / Evaluation of an SI engine running with gas of flow power heat trate from gasification of rice husk

Muraro, Wilson

24 February 2006

Orientador: Caio Glauco Sanchez / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecanica. / Made available in DSpace on 2018-08-06T19:32:34Z (GMT). No. of bitstreams: 1 Muraro_Wilson_M.pdf: 1394873 bytes, checksum: fc32a4e69a7d3e841edaf12eb62d7411 (MD5) Previous issue date: 2006 / Resumo: Hoje no mundo há uma grande rejeição de matériais, resíduos e outros compostos orgânicos que podem ser aproveitados como fontes de energia. Exemplos podem ser observados em todo o mundo e principalmente em regiões onde a pobreza impera e que a energia elétrica pode ser de grande ajuda ou mesmo como um salva vidas. O emprego de pequenas centrais de geração de potencia integradas a um gaseificador comum motor de combustão interna (Integrated Gasefication Combustion EngineI GCE) do ciclo OTTO e adaptado para operar com gás de baixo poder calorífico, constitui uma alternativa interessante e economicamente viável,que possibilita a produção independente de energia elétrica e térmica (Marcelo,2004). Para o aproveitamento de resíduos de BIOMASSA,como a casca de arroz, utilizou-se um processo de gaseificação,que é uma técnica que possibilita o uso energético da biomassa através da obtenção de um gás de baixo poder calorífico (4a6 MJ/Nm33). Utilizou-se um gaseificador de leito fluidizado do Laboratório de combustão da FEM,onde foi instalado um motor de 5965 litros de cilindrada total e 6 cilindros, com taxa de compressão 12:1, do ciclo OTTO, que originalmente é utilizado em veículos movidos a gás natural comprimido. Obteve se os seguintes valores nos ensaios: Potência (kW)=40.7@ 1800 rpm, Avanço(Graus do virabrequim )=30;Temperatura de Escapamento (°C) =596; Lambda =1,12; Pressão Máxima de Combustão (PA) =4000000. Como funcionamento do motor, verificou se a necessidade de algumas alterações em seus componentes, como também mudanças nas regulagens de avanço. É necessário um sistema para aumentar a pressão do gás proveniente do gaseificador e um sistema de partida inicial. Dessa maneira teríamos um motor para operar como grupo gerador e fazer parte de uma planta piloto para geração de energia elétrica por gaseificação de biomassa / Abstract: Nowadays there is a great waste of organic matters, residues and other substances that could be used in a power plant. Examples can mainly be observed in the whole world and in regions where the poverty reigns and where the electric energy could be of great aid.The use of small power generation plants integrated to a gasification with an internal combustion engine (Integrated Gasification Combustion Engine-GCE) of cycle OTTO and adapted to operate with low power heat rate gas, consists an interesting and economical viable alternative, that makes possible the independent production of electric and thermal energy. For the exploitation of residues of BIOMASS, as the rice husk, we used a gasification process that is a form to increase the energy use of the biomass. The gasification can generate thermal energy and electric energy. It was used gasifier of fluidized bed from UNICAMP, where it was installed an engine with of 5,965 liters and 6 cylinders, with compression rate 12:1(cycle OTTO),which was originally used in vehicles powered by compressed natural gas, to running with the gas of low power heat rate (46 MJ/Nm3) produced by gasifier. Typical experimental result. Power (kW)=40,7@1800rpm; Advance (Degrees)=30; Exhaust gas temperature(°C)=596; Lambda=1,12; Maximum Combustion Pressure (PA)=4000000. During the running of the engine, the necessity of some alterations in some components was verified as well changes in the advance regulations. A system to increase the pressure of the gas proceeding from the gasifier and a system of start are necessary. In this way we would have an engine to operate as generating group and to be part of a pilot plant for generation of eletric energy for gasification of biomass in agricultural and interior cities / Mestrado / Termica e Fluidos / Mestre em Engenharia Mecânica

Cinza de casca de arroz

Biomassa

Gaseificação

Gás

Biogas

Gas de gasogenio

Biomass

Gaseification

Natural gas

Lower power heat rate

Engine cycle OTTO

Rice husk