Upgrading of Oils from Biomass and Waste: Catalytic Hydrodeoxygenation
Abstract
:1. Introduction
- Conventional Pyrolysis: Pyrolysis at the slow heating rate, which permits the formation of the solid, liquid and gaseous products in significant portions.
- Fast Pyrolysis: If the procedure aims to produce a liquid or gaseous product, fast pyrolysis is employed. In this case, the products are considered marginal with a low yield. The operating conditions are declared: High operating temperature, short residence time and very fine particles.
- Flash Pyrolysis: In this method, the feedstock is directly fed into the high-temperature zone of the reactor, which subsequently undergoes flash pyrolysis where the final products are in the gaseous phase with a short contact time inside the reactor.
1.1. Oxygenated Compounds Exist in Biomass Pyrolysis Oil
1.2. Issues Related to the Presence of Oxygen in the Feedstock or Products
2. Different Deoxygenation Approaches for Bio-Oil
2.1. Physical Upgrading Technologies
2.1.1. Solvent Addition
2.1.2. Emulsion
2.2. Chemical Upgrading Technologies
2.2.1. Esterification
2.2.2. Supercritical Fluid
2.2.3. Steam Reforming
2.2.4. Hydrocracking
2.2.5. Hydrotreatment
3. Hydrodeoxygenation
Catalytic Hydrodeoxygenation
4. HDO Catalysts
4.1. Sulphide Catalysts
4.2. Oxide Catalysts
4.3. Transition Metal Catalysts
Phosphide, Carbide, and Nitride Catalysts
5. HDO of Different Biomass-Derived Oxygenates
5.1. HDO of Lignin-Derived Oxygenates
5.1.1. Phenol and Alkylated Phenol
5.1.2. Guaiacol
5.1.3. Phenolic Dimers
5.2. HDO of Carbohydrates-Derived Oxygenates
5.2.1. Levulinic Acid
5.2.2. Acrylic Acid
5.2.3. Furfurals
6. The Issue of Catalytic Deactivation in an Application and How It Can Be Solved
6.1. Coke Formation
6.2. Catalyst Deactivation
7. Techno-Economic Analysis of HDO
8. Applying the Microwave in the Hydrodeoxygenation Process
8.1. Microwave Heating
8.2. Applying the Microwave in the Case of the HDO Processes
Author Contributions
Funding
Conflicts of Interest
References
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Conventional | Fast | Flash | |
---|---|---|---|
Pyrolysis Temperature (K) | 550–950 | 850–1250 | 1050–1300 |
Heating Rate (K/s) | 0.1–1 | 10–200 | >1000 |
Particle Size (mm) | 5–10 | <1 | <0.2 |
Solid Residence Time (s) | 450–550 | 0.5–10 | <0.5 |
Material | C | H | O | N | S |
---|---|---|---|---|---|
Ash | 49.7 | 6.9 | 3.0 | - | - |
Beech | 51.6 | 6.3 | 41.4 | - | - |
Sawdust | 48.3 | 6.22 | 45.2 | 0.22 | 0 |
Barley Straw | 45.7 | 6.1 | 38.3 | 0.4 | 0.1 |
Bituminous Coal | 73.1 | 5.5 | 8.7 | 1.4 | 1.7 |
Cypress | 55.0 | 6.5 | 38.1 | - | - |
Kraft lignin | 63.3 | 5.8 | 29.2 | 0.1 | 1.6 |
Miscanthus | 48.1 | 5.4 | 42.2 | 0.5 | <0.1 |
Rice Straw | 41.4 | 5 | 39.9 | 0.7 | 0.1 |
Wood | 51.6 | 6.3 | 41.5 | - | 0.1 |
Wheat Straw | 48.5 | 5.5 | 3.9 | 0.3 | 0.1 |
Material | C | H | O | N | S |
Component | Structure | Area wt.% |
---|---|---|
Formaldehyde | 3.14 | |
Hydroxyacetaldehyde | 3.14 | |
Hydroxypropanone | 2.70 | |
Butyric acid | 0.96 | |
Acetic acid | 29.76 | |
Glyceraldehyde | 3.54 | |
2,2-dimethoxy-ethanol | 6.83 | |
Furfural | 6.56 | |
2,5-dimethoxy-tetrahydrofuran | 3.47 | |
4-hydroxy-butyric acid | 0.43 | |
5H-furan-2-one | 0.74 | |
2-Furoic acid | - | |
2,3-dimethyl-cyclohexanol | 1.31 | |
3-methyl-5H-furan-2-one | 0.38 | |
Phenol | 1.57 | |
o-cresol | 1.12 | |
m-cresol | 1.46 | |
2-methoxy-6-methyl-phenol | 1.78 | |
3,4-dimethyl-phenol | 1.14 | |
4-ethyl-phenol | 1.31 | |
Catechol | 3.53 | |
3-methyl-catechol | 1.36 | |
Vanillin | 0.24 | |
4-ethyl-catechol | 0.71 | |
Levoglucosan | 9.95 | |
2,3,4-trimethoxy-benzaldehyde | 0.20 | |
3-(4-hydroxy-2-methoxy-phenyl)-propenal | 0.15 |
Properties | Bio-Oil from Fast Pyrolysis | Heavy Fuel |
---|---|---|
Water (wt.%) | 15–30 | 0.1 |
pH | 2–4 | - |
Density (kg/m3) | 1200 | 940 |
Elemental composition (wt.%) | ||
C | 48–65 | 83–86 |
H | 5.5–7 | 11–14 |
O | 30–45 | <1 |
N | 0–0.3 | <0.3 |
S | <0.05 | <3.0 |
HHV (MJ/kg) | 16–19 | 40 |
Viscosity (cP, 50 ℃) | 40–100 | 180 |
Ash (wt.%) | 0–0.2 | 0.1 |
Solids (wt.%) | 0.2–1 | 1 |
Distillation residue (wt.%) | <50 | 1 |
NOx emission | <0.7 | 1.4 |
SOx emission | 0 | 0.28 |
Upgrading Approach | Advantages | Disadvantages |
---|---|---|
Emulsion | Easy-operation | High-cost of surfactant; high energy consumption; cannot remove unfavourable substances |
Solvent addition | Easy-operation | Cannot remove unfavourable substances |
Hydrocracking | The formation of light components | The requirement for a high-pressure resistant reactor, coke formation; catalyst deactivation; high-pressure H2 is needed |
Hydrotreatment | Well-established treatment in oil refineries; effectively removes heteroatoms | The requirement for a high-pressure resistant reactor; coke formation; catalyst deactivation; high-pressure H2 is needed |
Steam reforming | Highly energy-dense H2 as the main product | The requirement for high-temperature-resistant reactor |
Supercritical fluids | Significantly lowers the viscosity and increases HHV of bio-oil | High-cost of the solvent; requirement for high-pressure resistant reactor |
Esterification | Easy-operation; moderate reaction conditions | Cannot remove nitrogenates and thus cannot be used for algae-derived bio-oil |
Catalyst | Oxygenate Compound | Deoxygenated Compound | Reference |
---|---|---|---|
NiMoS | Phenol | Cyclohexane, Benzene, Cyclohexene | [68] |
MoS2 | Guaiacol | Phenol, cyclohexane, benzene, methyl cyclopentane | [69] |
MoS | Phenol | Benzene, cyclohexene, cyclohexane | [70] |
NiMoS | 2,3-dihudro benzofuran | 2-Ethylphenol, ethyl cyclohexane | [71] |
NiMo, CoMo | Waste cooking oils | n-paraffins, isoparaffins, a small amount of olefins | [72] |
CoMoWS/SBA-15 | Anisole | Phenol, cresol, xylenol | [73] |
CoMoS/MgO | Phenol | 2-Cyclohexylphenol, cyclohexylbenzene, cyclohexanol | [74] |
CoMoS | Phenol | Benzene, cyclohexane, Cyclohexene | [70] |
Ni-Mo | 2,3-dihydro benzofuran | Ethyl benzene, ethyl-cyclohexane, ethylcyclohexene, methylcyclohexane, and cyclohexane | [71] |
ReS2/AC | Guaiacol | Phenol, catechol | [75] |
Feedstock | Catalyst | Conclusions | Ref. |
---|---|---|---|
Eugenol + Light fraction of bio-oil | Ni-based | Highest product selectivity of propyl-cyclohexane was 67.9% and all eugenol can be converted Al-SBA-15 was mixed with ZSM-5 as the support to enhance the catalytic activity The presence of acetic acid and furfural affected the HDO of eugenol | [90] |
Fast pyrolysis bio-oil | MoS2 | 90% of O from the bio-oil was removed The formation of coke was not obvious | [66] |
Phenolics and bio-oil | Ru-based | Guaiacol was converted into cycloalkanes 29.1% of hydrocarbons and 41.3% of alkylphenols were produced from HDO of bio-oil Dispersed Ru and moderate acid site improved the HDO reaction | [91] |
Fast pyrolysis bio-oil | β-Mo2C | The HHV of upgraded bio-oil was 41.1 MJ/kg; Catalyst was highly stable upon recycling and it was easy to recycle | [81] |
m-Cresol | Ru-based | Ru/ZSM-5 was the best catalyst in terms of the 100% product yield, 240 h of lifetime, and was used for 4 cycles | [92] |
Fast pyrolysis bio-oil | NbMo/C | HDO at 300 °C for 60 min lower the O and moisture content to 19% and 0.1%, respectively; Coke formation was observed. The viscosity, density, and stability of upgraded bio-oil were comparable to those of petroleum | [93] |
Cyclohexanone | Co-based | Catalyst had high catalytic activity and selectivity for cyclohexanone to produce cyclohexane, cyclohexene, benzene, and cyclohexylbenzene 100% of hydrocarbon selectivity and 89% of cyclohexanone conversion were obtained at 400 °C and 15 bar of H2 | [94] |
Cyclohexanone | NiMo-based | C6, C7, C12 cyclic, aromatic, and bicyclics were the main products; 87% of cyclohexanone conversion was obtained at 400 °C and 8 bar of H2 | [95] |
Fast pyrolysis bio-oil | Pt and MoO3-based and Mo-based industrial catalyst | All catalysts reduced O content of bio-oil to 7–12 wt.%; Pt catalyst showed better performance to lower acidic value; more coke was formed using Mo-based industrial catalyst | [96] |
Phenol | Rh, Pd, Ni-based | The order for the catalytic activity was: Pd > Rh > Ni when performing reduction at 300 °C while no difference in the catalytic activity at reduction of 500 °C | [97] |
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Attia, M.; Farag, S.; Chaouki, J. Upgrading of Oils from Biomass and Waste: Catalytic Hydrodeoxygenation. Catalysts 2020, 10, 1381. https://doi.org/10.3390/catal10121381
Attia M, Farag S, Chaouki J. Upgrading of Oils from Biomass and Waste: Catalytic Hydrodeoxygenation. Catalysts. 2020; 10(12):1381. https://doi.org/10.3390/catal10121381
Chicago/Turabian StyleAttia, Mai, Sherif Farag, and Jamal Chaouki. 2020. "Upgrading of Oils from Biomass and Waste: Catalytic Hydrodeoxygenation" Catalysts 10, no. 12: 1381. https://doi.org/10.3390/catal10121381
APA StyleAttia, M., Farag, S., & Chaouki, J. (2020). Upgrading of Oils from Biomass and Waste: Catalytic Hydrodeoxygenation. Catalysts, 10(12), 1381. https://doi.org/10.3390/catal10121381