The amount of components (primarily hydrocarbon derivatives) other than carbon monoxide and hydrogen can be reduced via their further transformation into carbon monoxide and hydrogen. This is, however, rather energy intensive and costly (two processes – gasification and transformation). As a result, the overall energy efficiency of syngas production and of biomass-to-liquids processing is also reduced.
The amount of various components can be minimized via a more complete decomposition of biomass, thereby preventing the formation of undesirable components at the gasification step. This approach seems to be more appropriate for energy efficiency. The minimization of the content of various hydrocarbon derivatives is achieved by increasing temperatures in the gasifier, along with shortening the residence time of feedstocks inside the reactor. Because of this short residence time, the particle size of feedstocks should be small enough (in any case – smaller than in gasification for power generation) in order that complete and efficient gasification can occur.
In gasification for power generation, typically, air is employed as an oxidizing agent, as it is indeed the cheapest among all possible oxidizing agents. However, the application of air results in large amounts of nitrogen in the product gas, since nitrogen is the main constituent of air. The presence of such large quantities of nitrogen in the product gas does not hamper (very much) power generation, but it does hamper liquids production. Removing this nitrogen via liquefaction under cryogenic temperatures is extremely energy intensive, reduces substantially the overall biomass-to-liquids energy efficiency, and increases costs. Among other potential options (steam, carbon dioxide, carbon monoxide), from a techno-economic point of view, oxygen appears to be the most suitable oxidizing agent for biomass-to-liquids manufacturing.
The air-blown direct gasifiers operated at atmospheric pressure and used in power generation – fixed bed updraft and downdraft and fluidized bed bubbling and circulating – are not suitable for biomass-to-liquids production. In addition, downdraft fixed bed gasifiers face severe constraints in scaling and are fuel inflexible, being able to process only fuels with well-defined properties.
Updraft fixed bed gasifiers have fewer restrictions in scaling (usually up to 10 MW), but the produced gas contains a lot of tars and methane. However, fluidized bed gasifiers generally do not encounter limitations in scaling and are more flexible concerning the particle size of fuels. Nevertheless, they still have limited fuel flexibility, due to a risk of slagging and fouling, agglomeration of bed material, and corrosion. The operating temperatures of air-blown fluidized bed gasifiers are therefore kept relatively low (800 to 1,000°C, 1,470 to 1,830°F), which implies incomplete decomposition of feedstocks, unless long residence times are used.
Fluidized bed gasifiers (especially the bubbling bed gasifiers) tend to contaminate the product gas with dust. The oxygen-blown atmospheric or pressurized circulating fluidized bed gasifiers and the steam-blown gas or char indirect gasifiers are better solutions for biomass-to-liquids processes. Both gasifying concepts significantly reduce the amount of nitrogen in the product gas. In the first case, it is achieved via substituting air with oxygen. In the second case, nitrogen ends up in the flue gas, but not in the product gas, because gasification and combustion are separated – the energy for the gasification is obtained by burning the chars from the first gasifier in a second reactor.
Nonetheless, both oxygen-blown circulating bed gasifiers and steam-blown indirect gasifiers still present some major weak points with regard to biomass-to-liquids processes. In the former case, the issues related to the necessity for further cracking of the unconverted hydrocarbon derivatives and with the high dust emissions are still relevant. In the latter case, these two drawbacks can be overcome, but at the expense of a significant increase in capital costs, since two reactors are needed instead of just one. In fact, the case of the gas indirect gasifier also involves a second reactor. Finally, indirect gasifiers carry a higher risk of malfunctioning and are less reliable, because of their more sophisticated configuration.
Considering the above reasons, the pressurized oxygen-blown direct entrained flow gasifier appears to be the most suitable gasification concept to obtain synthesis gas for later biomass-to-liquids processes. Entrained flow gasifiers do not encounter severe scaling restrictions, and their capacity can easily be of several hundred MW. They also represent a mature technology for coal (not for biomass!), which has been employed for years. Entrained flow gasifiers operate at elevated pressures and much higher temperatures (1,200 to 1,500°C, 2,190 to 2,730°F) than other gasifiers (usually below 900ºC, 1,650°F). The residence time of the fuel is also much shorter (a few seconds) compared to that in other gasifiers.
For a complete transformation of the feedstock into synthesis gas within such short residence time, its particle size also has to be smaller than that required for other gasifiers – not larger than 1 mm, typically below 0.1 mm (100 μm, 100 microns). With such extreme conditions, almost tar-free synthesis gas with high content of carbon monoxide and hydrogen is obtained. This high conversion rate is also facilitated by the high reactivity and volatility of biomass. Conversely, the maximization of the liquids yield, i.e., of the content of CO and H2 in the product gas, results in 10 to 15% lower total transformation efficiency (when other useful products from gasification are also counted) compared to other gasifying concepts.
Many feedstocks have high content of ash, which under high temperature turns into molten slag. Molten slag also retains some undesirable compounds of biomass, e.g., heavy metals. The removal of molten slag from the bottom of the reactor has to be incorporated into its design – a slagging-type entrained flow gasifier. In order to improve slag properties, the addition of fluxing material (silica sand or limestone) is necessary. In contrast, in non-slagging entrained flow gasifiers, the removal of molten slag is not foreseen. Hence, non-slagging gasifiers are fuel inflexible, suitable only for clean feedstocks with low mineral (ash) content (less than 1%), e.g., oils.
The energy efficiency of gasification is further reduced by the removal of large quantities of inert gas (usually carbon monoxide) from the product gas. Inert gas is employed as a medium for lock hopper pressurization and pneumatic feeding of pulverized material (a mandatory feeding option for finely pulverized fuels) into the reactor. The amount of inert gas depends on the bulk density of fuels – the lower the density, the larger the amount. The low bulk density of biomass implies large consumption of carbon dioxide, and alternative forms of biomass feedstock (via pre-treatment) have to be considered for entrained flow gasifiers. The most feasible biomass pre-treatment options are torrefaction, pyrolysis, and pre-gasification.
See also: Biomass – Gasification, Gasifiers, Synthesis Gas.
Biomass to Energy
The old way of converting biomass to energy, practiced for thousands of years, is simply to burn it to produce heat (one of final forms of energy). The problems with burning biomass are that much of the energy is wasted and that it can cause some pollution if it is not carefully controlled. A number of non-combustion methods are available for converting biomass to energy. These processes convert raw biomass into a variety of gaseous, liquid, or solid fuels that can then be used directly in a power plant for energy generation. The carbohydrates in biomass, which are comprised of oxygen, carbon, and hydrogen, can be broken down into a variety of chemicals, some of which are useful fuels. This conversion can be done in three ways: (i) thermochemical methods, (ii) biochemical methods, and (iii) physical methods.
When plant matter is thermally decomposed, it breaks down into various gases, liquids, and solids. These products can then be further processed and refined into useful fuels such as methane and alcohol. Biomass gasifiers capture methane released from the plants and burn it in a gas turbine to produce electricity. Another approach is to take these fuels and run them through fuel cells, converting the hydrogen-rich fuels into electricity and water, with few or no emissions.
Biochemical