4.3: Gasification

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4.3 Gasification

Now, we will go into gasification and compare it to combustion. Gasification is a process that produces syngas, a gaseous mixture of CO, CO₂, H₂, and CH₄, from carbonaceous materials at high temperatures (750 – 1100°C). Gasification is a partial oxidation process; reaction takes place with a limited amount of oxygen. The overall process is endothermic (requires heat to keep the reaction going), so it requires either the simultaneous burning of part of the fuel or the delivery of an external source of heat to drive the process.

Historically, gasification was used in the early 1800s to produce lighting, in London, England (1807) and Baltimore, Maryland (1816). It was manufactured from the gasification of coal. Gasification of coal, combined with Fischer-Tropsch synthesis was one method that was used during WWII to produce liquid fuel for Germany because they did not have access to oil for fuel. It has also been used to convert coal and heavy oil into hydrogen for the production of ammonia and urea-based fertilizer. As a process, it continues to be used in South Africa as a source for liquid fuels (gasification followed by Fischer-Tropsch synthesis).

Gasification typically takes place at temperatures from 750-1100°C. It will break apart biomass (or any carbon material), and usually, an oxidizing agent is added in insufficient quantities. The products are typically gas under these conditions, and the product slate will vary depending on the oxidizing agent. The products are typically hydrogen, carbon monoxide, carbon dioxide, and methane. There may also be some liquid products depending on the conditions used. Gasification and combustion have some similarities; Figure 4.5 shows the variation in products between gasification and combustion. Table 4.2 shows a comparison of the conditions.

Combustion produces, CO2, H2O, NOx, SOx, & Ash versus gasification which produces CO, H2, N2, H2S & inert aggregates — Figure 4.5: Diagram showing the different products of Combustion and Gasification from carbon, hydrogen, nitrogen and sulfur.

*Credit: Dr. Caroline B. Clifford*

Table 4.2: Comparison of Combustion versus Gasification

Specification	Combustion	Gasification
Oxygen Use	Uses excess	Uses limited amounts
Process Type	Exothermic	Endothermic
Product	Heat	Combustible Synthesis

Zones of Gasification

There are several zones that the carbon material passes through as it proceeds through the gasifier: 1) drying, 2) pyrolysis, 3) combustion, and 4) reduction. The schematic in Figure 4.6 shows the zones and the products that typically occur during that part of the process. First, we will discuss what happens in each zone. We will also be looking at different gasifier designs to show these zones change depending on the design, and each design has advantages and disadvantages.

The drying process is essential to remove surface water, and the “product” is water. Water can be removed by filtration or evaporation, or a combination of both. Typically, waste heat is used to do the evaporation.

general schematic of different regions in gasifier, see text description below — Figure 4.6: General schematic of different regions in a gasifier.

Click here for a text alternative of figure 4.6

Diagram showing different regions and products in a gasifier. Heat is applied to the entire system, oxidizing agents such as air, O2, H2O, and CO2 enter from the bottom and biomass enters from the top.

The biomass first goes through drying which removes water. It then goes through pyrolysis which produces char, tar and methane. From pyrolysis the biomass can go to reduction or combustion which produces carbon dioxide and water. If the biomass goes through combustion it also then goes to reduction which produces hydrogen gas and carbon monoxide.

*Credit: Dr. Caroline B. Clifford*

Pyrolysis is typically the next zone. If you look at it as a reaction:

Reaction 1: Dry biomass → Volatiles + Chars (C) + Ash

Reaction 2: Volatiles → (x) Tar +(1−x) Gas

where x is the mass fraction of tars in the volatiles. Volatile gases are released from the dry biomass at temperatures ranging up to about 700oC. These gases are non-condensable vapors such as CH₄, CO, CO₂ and H₂ and condensable vapor of tar at the ambient temperature. The solid residues are char and ash. A typical method to test how well a biomass material will pyrolyze is thermogravimetric analysis; it is similar to the proximate analysis. However, the heating rate and oxidizing agent can be varied, and the instrument can be used to determine the optimum temperature of pyrolysis.

Gasification Process and Chemistry: Combustion and Reduction

A limited amount of oxidizing agent is used during gasification to partially oxidize the pyrolysis products of char (C), tar and gas to form a gaseous mixture of syngas mainly containing CO, H₂, CH₄ and CO₂. Common gasifying agents are: air, O₂, H₂O and CO₂. If air or oxygen is used as a gasifying agent, partial combustion of biomass can supply heat for the endothermic reactions.

Reaction 3: C (char) + O₂=CO₂

Reaction 4 C_mH_n(tar) + (m + n/4)O₂→mCO₂+n/2H₂O

Combustion of gases:

Reaction 5: H₂+1/2O₂→H₂O

Reaction 6: CH₄+2O₂→CO₂+2H₂O

Reaction 7: CO +1/2O₂→CO₂

The equivalence ratio (ER) is the ratio of O₂ required for gasification, to O₂ required for full combustion of biomass. The value of ER is usually 0.2 - 0.4. At too high ER values, excess air causes unnecessary combustion of biomass and dilutes the syngas. At too low ER values, the partial combustion of biomass does not provide enough oxygen and heat for gasification.

There are several reactions that can take place in the reduction zone. There are three possible types of reactions: 1) solid-gas reactions, 2) tar-gas reactions, and 3) gas-gas reactions. Essentially, H₂O and CO₂ are used as gasifying agents to increase the H₂ and CO yields. The double-sided arrow represents that these reactions are reversible depending on the conditions used.

Solid-gas reactions include:

Reaction 8: C + CO₂↔ 2CO (Boudouard Reaction)

Reaction 9: C + H₂O ↔ CO + H₂(Carbon-Water Reaction)

Reaction 10: C + 2H₂↔CH₄(Hydrogenation Reaction)

Tar-gas reactions include:

Reaction 11: C_mH_n(tar) + mH₂O ↔ (m+n/2)H₂+ mCO (Tar Steam Reforming Reaction)

Reaction 12: C_mH_n(tar) + mCO₂↔ n/2H₂+ 2mCO (Tar Dry Reforming Reaction)

Gas-gas reactions include:

Reaction 13: CO + H₂O↔CO₂+ H₂(Water-Gas Shift Reaction)

Reaction 14: CO + 3H₂↔CH₄+ H₂O (Methanation)

The reactions can be affected by reaction equilibrium and kinetics. For a long reaction time: 1) chemical equilibrium is attained, 2) products are limited to CO, CO₂, H₂, and CH₄, and 3) low temperatures and high pressures favor the formation of CH₄, whereas high temperatures and low pressures favor the formation of H₂ and CO. For a short reaction time: 1) chemical equilibrium is not attained, 2) products contain light hydrocarbons as well as up to 10 wt% heavy hydrocarbons (tar), and 3) steam injection and catalysts can shift the products toward lower molecular weight compounds.

Gasifier Designs

There are several types of gasifier designs: 1) updraft, 2) downdraft, 3) cross downdraft, 4) fluidized bed, and 5) plasma. The first type of gasifier is the updraft (Figure 4.7) design. The advantages include that it is a simple design and is not sensitive to fuel selection. However, disadvantages include a long start-up time, production of high concentrations of tar, and general lack of suitability for modern heat and power systems.

The downdraft gasifier (Figure 4.8) is similar, but the air enters in the middle of the unit and gases flow down and out. The oxidation and reduction zones change places. Advantages to this design include low tar production, low power requirements, a quicker response time, and a short start up time. However, it has a more complex design, fuel can be fouled with slag, and it cannot be scaled up beyond 400 kg/h.

updraft design gasifier, see text description below — Figure 4.7: Updraft design gasifier.

Click here for a text alternative of figure 4.7

Schematic of an Updraft Gasifier. The diagram looks like a cylinder with oxidizing gas entering at the bottom and flowing up and out at the top. There are 5 layered zones in the gasifier. Starting at the bottom there is the ash zone, the oxidation zone, the reduction zone, the pyrolysis zone and the drying zone.

*Credit: Dr. Caroline B. Clifford*

downdraft design gasifier, see text description below — Figure 4.8: Downdraft design gasifier.

Click here for a text alternative of figure 4.8

Schematic of a downdraft gasifier. The diagram again looks like a cylinder and again has 5 layered zones. From the bottom up they are, the ash pit, the reduction zone, the oxidation zone, the pyrolysis zone, the drying zone. The air enters in the middle of the gasifier at the oxidation zone and the air flows down and comes out the bottom as product gas.

*Credit: Dr. Caroline B. Clifford*

The crossdraft design gasifier is shown in Figure 4.9. Similar to the downdraft, it has a quicker response time and has a short start up time; it is also complex in design, cannot use high mineral containing fuels, and fuel can be contaminated with slag from ash.

A fluidized bed design gasifier is shown in Figure 4.10. The action of this gasifier is similar to how water might boil, except the air (or other gas) flows through the fines (the sample and sand) at temperature, creating a bubbling effect similar to boiling. Because of this action, it has the advantages of greater fuel flexibility, better control, and is quick in response to changes. But because of these advantages, these types of gasifiers have a higher capital cost, a higher power requirement, and must be operated on high particulate loading.

crossdraft design gasifier, see text description below — Figure 4.9: Crossdraft design gasifier.

Click here for a text alternative of figure 4.9

Schematic of a crossdraft gasifier. This gasifier again looks like a cylinder and has all 5 of the zones the previous 2 did. However, instead of layers, the zones look more like a bullseye. Air enters halfway up the cylinder in the very center which is the oxidation zone. Around the oxidation zone is the reduction zone and outside that is the pyrolysis zone. The drying zone is around them all. The ash pit is still a layer at the very bottom. Product gas comes out at the same level the air initially came in.

*Credit: Dr. Caroline B. Clifford*

fluidized bed design gasifier, see text description below — Figure 4.10: Fluidized bed design gasifier.

Click here for a text alternative of figure 4.10

Schematic of a fluidized bed design gasifier. This gasifier looks like a cylindrical capsule where air, oxygen or steam enters from the bottom. Near the bottom there is distributor plate. The fluidized bed with the fuel sits on top of the plate and at the bottom of the fluidized bed there is an exit for the ash. There is a mechanism to recirculate the fines near the top of the fluidized bed. To exit, the gas flows through a cyclone and out the top of the gasifier.

*Credit: FAO©. Accessed March 28, 2014.*

One of the new design gasifiers is a plasma gasifier design. Plasma gasification uses extremely high temperatures in an oxygen-starved environment to decompose waste material into small molecules and atoms, so that the compounds formed are very simple and form a syngas with H₂, CO and H₂O. This type of unit functions very differently, as electricity is fed to a torch that has two electrodes – when functioning, the electrodes create an arc. Inert gas is passed through the arc, and, as this occurs, the gas heats to temperatures as high as 3,000 °C (Credit: Westinghouse Plasma Corporation). The advantages of such units include: 1) process versatility, 2) superior emission characteristics, 3) no secondary treatment of byproducts, 4) valuable byproducts, 5) enhanced process control, 6) volume reduction of material fed, and 6) small plant size. Units such as these are more expensive and scaling up is still in the research stage. These types of units are most commonly used for municipal waste sludge.

plasma design gasifier, see text description below — **Figure 4.11: Plasma design gasifier.**

Click here for a text alternative of figure 4.11

Schematic of a plasma design gasifier. This looks like a funnel with a lid. About halfway up there is a waste inlet. Below that there is an inlet for air or oxygen and near the bottom there are plasma torches. The syngas exits from an outlet at the top and slag and recovered metals are collected from an outlet at the bottom.

*Credit: Westinghouse Plasma Corporation*

General information on gasification

So what products are made, what advantages are there to using various oxidizing sources, how are the byproducts removed, and how is efficiency improved? Besides syngas, other products are made depending on the design. As stated previously, the syngas is composed of H₂, CO, CO₂, H₂O, and CH₄. Depending on the design, differing amounts of tar and char can also be made. For example, for steam fluidized gasification of wood sawdust at atmospheric pressure and 775°C, 80% of the carbon will be made into syngas, 4% of the carbon will produce tar, and 16% will produce char (Herguido J, Corella J, Gonzalez-Saiz J. Ind Eng Chem Res 1992; 31: 1274-82.)

There are multiple uses for syngas, for making hydrocarbon fuels, for producing particular chemicals, and for burning as a fuel; therefore, syngas has a heating value. The heating value can be calculated by the volumetric fraction and the higher heating values (HHV) of gas components, which is shown in this equation:

HHV_gas= VCO (HHVCO) + VCO2 (HHVCO2)+VCH4 (HHVCH4)

+V_H2(HHV_H2) + V_H2O(HHV_H2O)+V_N2(HHV_N2)

where:

HHV_CO=12.68 MJ/Nm³

HHV_CO2=0.00MJ/Nm³

HHV_CH4=38.78MJ/Nm³

HHV_H2=12.81MJ/Nm³

HHV_H2O=2.01MJ/Nm³

HHV_N2=0.00MJ/Nm³

A problem based on this equation and HHVs will be included in the homework.

Other factors are determined for optimal gasification. Thermal efficiency is the conversion of the chemical energy of solid fuels into chemical energy and sensible heat of gaseous products. For high temperature/high pressure gasifiers, the efficiency is high, ~90%. For typical biomass gasifiers, the efficiency is reduced to 70-80% efficiency. Cold gas efficiency is the conversion of chemical energy of solid fuel to chemical energy of gaseous products; for typical biomass gasifiers, the efficiency is 50-60%.

There are several processing factors that can affect different aspects of gasification. Table 4.3 shows the main advantages and technical challenges for different gasifying agents. Steam and carbon dioxide as oxidizing agents are advantageous in making a high heating value syngas with more hydrogen and carbon monoxide than other gases, but also require external heating sources and catalytic tar reformation.

Table 4.3: Advantages and technical challenges of different gasifying agents. (Wang, LJ, Well, CL, Jones, DD and Hanna, MA. 2008. Biomass and Bioenergy, 32:573-581.)

Gasifying Agent	Main Advantages	Main Technical Challenges
Air	Partial combustion for heat supply of gasification. Moderate char and tar content.	Low heating value (3-6 MJ/Nm³) Large amount of N₂ in syngas (i.e., >50% by volume) Difficult determination of equivalence ratio (ER)
Steam	High heating value syngas (10-15 MJ/Nm³) H₂-rich syngas (i.e., >50% by volume)	Requires indirect or external heat supply for gasification High tar content in syngas Tar requires catalytic reforming to syngas unless used to make chemicals
Carbon dioxide	High heating value syngas High H₂/CO and low CO₂ in syngas	Requires indirect or external heat supply Tar requires catalytic reforming to syngas unless used to make chemicals

Gasifying Agent

Main Advantages

Main Technical Challenges

Air

Partial combustion for heat supply of gasification.

Moderate char and tar content.

Low heating value (3-6 MJ/Nm³)

Large amount of N₂ in syngas (i.e., >50% by volume)

Difficult determination of equivalence ratio (ER)

Steam

High heating value syngas (10-15 MJ/Nm³)

H₂-rich syngas (i.e., >50% by volume)

Requires indirect or external heat supply for gasification

High tar content in syngas

Tar requires catalytic reforming to syngas unless used to make chemicals

Carbon dioxide

High heating value syngas

High H₂/CO and low CO₂ in syngas

Requires indirect or external heat supply

Tar requires catalytic reforming to syngas unless used to make chemicals

Basic design features can also affect the performance of a gasifier. Table 4.4 shows the effect of fixed bed versus a fluidized bed and differences in temperature, pressure, and equivalence ratio. Fixed/moving beds are simpler in design and favorable on a small scale economically, but fluidized bed reactors have a higher productivity and low byproduct generation. The rest of the table shows how increased temperature can also favor carbon conversion and the HHV of the syngas, while increased pressure helps with producing a high pressure syngas without compression to higher pressures downstream.

Table 4.4: Effect of bed design and differences in operating parameters on gasifier operation. (Wang, LJ, Weller, CL, Jones, DD and Hanna, MA. 2008. Biomass and Bioenergy, 32: 573-581.)

Bed Design	Main Advantages	Main Technical Challenges
Fixed/moving bed	Simple and reliable design Favorable economics on a small scale	Long residence time Non-uniform temperature distribution in gasifiers High char and/or tar contents Low cold gas efficiency Low productivity (i.e., ~5 GJ/m²h)
Fluidized bed	Short residence time High productivity (i.e., 20-30 GJ/m²h) Uniform temperature distribution in gasifiers Low char and/or tar contents High cold gas efficiency Reduced ash-related problems	High particulate dust in syngas Favorable economics on a medium to large scale
Increase of temperature	Decreased tar and char content Decreased methane in syngas Increased carbon conversion Increased heating value of syngas	Decreased energy efficiency Increased ash-related problems
Increase of pressure	Low tar and char content No costly syngas compression required for downstream utilization of syngas	Limited design and operational experience Higher cost of gasifier at small scale
Increase of ER (Equivalence Ratio)	Low tar and char content	Decreased heating value of syngas

Product Cleaning

The main thing that has to be done to clean the syngas is to remove char and tar. The char is typically in particulate form, so the particulates can be removed in a way similar to what was described in the power plant facility. Typically for gasifiers, the method of particulate filtration includes gas cyclones (removal of particulate matter larger than 5 μm). Additional filtration can be done using ceramic candle filters or moving bed granular filters.

Tars are typically heavy liquids. In some cases, the tars are removed by scrubbing the gas stream with a fine mist of water or oil; this method is inexpensive but also inefficient. Tars can also be converted to low molecular weight compounds by “cracking” into CO and H₂ (these are typically the desired gases for syngas). This is done at high temperature (1000°C) or with the use of a catalyst at 600-800°C. Tars can also be “reformed” to CO and H₂, which can be converted into alcohols, alkanes, and other useful products. This is done with steam and is called steam reforming of tar; the reaction conditions are at a temperature of ~250°C and pressure of 30-55 atm. The reaction is shown below, and is the same reaction as that shown in reaction 11:

Tar steam reforming reaction:

Reaction 11: C_mH_n(tar) + mH₂O ↔ (m+n/2)H₂+ mCO

Steam reforming has advantages. It is generally a safer operation since there isn’t any oxygen in the feed gases, and it produces a higher H₂/CO ratio syngas product than most alternatives. The main disadvantage is a lower thermal efficiency, as heat must be added indirectly because the reaction is endothermic.

Syngas Utilization

As stated earlier, syngas has multiple uses. Syngas can be used to generate heat and power, and can even be used to turn a turbine in some engineering designs. Syngas can also be used as the synthesis gas for Fischer-Tropsch fuel production, synthesis of methanol and dimethyl ether (DME), fermentation for production of biobased products, and production of hydrogen.

So, how is syngas utilized in heat and power generation? Syngas can be used in pulverized coal combustion systems; it helps the coal to ignite and to prevent plugging of the coal feeding system. Biomass gasification can ease ash-related problems. This is because the gasification temperature is lower than in combustion, and once gasified, can supply clean syngas to the combustor. Adding a gasifier to a combustion system helps in utilization of a variety of biomass sources with large variations in properties. Once the syngas has been cleaned, it can be fed to gas engines, fuel cells or gas turbines for power generation.

Syngas may also be used to produce hydrogen. When biomass is gasified, a mixture of H₂, CO, CH₄, and CO₂ is produced. Further reaction to hydrogen can be done using water reforming and water-gas shift reactions:

Water reforming reaction for CH₄ to H₂:

Reaction 15: CH₄+ H₂O ↔ 3H₂+ CO

Water-gas shift reaction for CO to H₂ (as shown earlier):

Reaction 13: CO + H₂O ↔ CO₂+H₂

Carbon dioxide may also be removed, as it is typically an undesirable component. One method to keep it from going into the atmosphere is to do chemical adsorption:

Reaction 16: CaO + CO₂↔CaCO₃

Syngas can also be utilized for Fischer-Tropsch synthesis of hydrocarbon fuels. Variable chain length hydrocarbons can be produced via a gas mixture of CO and H₂ using the Fischer-Tropsch method. The reaction for this is:

Reaction 17: CO + 2H₂→(-CH2-)n+H₂O

In order for the reaction to take place, the ratio should be close to 2:1, so gases generated via gasification may have to be adjusted to fit this ratio. Inert gases also need to be reduced, such as CO₂ and contaminants such as H₂S, as the contaminants may lower catalyst activity.

Methanol and dimethyl ether can also be produced from syngas. The reactions are:

Reaction 18: CO + 2H₂→CH₃OH

Reaction 19: CO₂+3H₂→CH₃OCH₃+H₂O

Dimethyl ether (DME) can be made from methanol:

Reaction 20: 2 CH₃OH→CH₃OCH₃+H₂O

Syngas can also be fermented to produce bio-based products. This will be discussed in detail in a later lesson.