Linking Energy- and Land-Use Systems: Energy Potentials and Environmental Risks of Using Agricultural Residues in Tanzania
Abstract
:1. Introduction
2. Research Objectives
3. Results and Discussion
3.1. Assessment of the Residue and Energy Potentials
3.1.1. The Commercial Agricultural Crop Sector in Tanzania
3.1.2. Types of Residues and Potential Availability in the Commercial Crop Sector
Crop | Annual Crop Production [t] 1 | Process Residues | Field Residues | RPR 2 | Annual Residue Production [t] | Harvesting season [month/ year] | Availability of residues |
---|---|---|---|---|---|---|---|
Sugar Cane | 2,046,500 | Bagasse | 0.30 | 613,950 | 8 | Nearly 100% is already utilized as boiler fuel to generate electricity for the sugar mills & plantations | |
Cane tops & leaves | 0.29 | 593,485 | 8 | None—Nearly 100% are burnt in-field to facilitate harvesting | |||
Coffee | 49,228 | Husks | 0.25 | 12,307 | 6 | Available at the processing plants | |
Cherry pulp & skin | 1.40 | 68,919 | 6 | Mostly wet coffee processing: pulp and outer skins are removed in decentralized locations during harvest & not centrally available for energy generation | |||
Cotton | 232,959 | Stalks | 2.20 | 512,510 | 3-4 | Stalks are left or burnt in the field after picking the cotton, stalks are also used as fuel for fire-stoves by poor families | |
Cashew nut | 92,906 | Shells | 2.10 | 195,103 | 4 | Only about 17% are processed (shelled) in Tanzania, the rest is exported as raw nut so that shells are not available | |
Tea | 29,060 | Stalks | 1.20 | 34,872 | 12 | Are left on the field as fertilizer | |
Tobacco | 39,613 | Stems | 0.95 | 37,632 | 4-5 | ||
Stalks | 2.00 | 79,226 | |||||
Sisal | 25,950 | Sisal pulp | 24.00 | 622,800 | 12 | All available at the processing plants, currently not utilized due to liquid nature, (besides small amount in a biogas pilot plant); in the future possible use as fodder (testing stage) | |
Sisal ball | 4.70 | 121,965 | Currently burnt or broken down & plowed under |
3.1.3. Theoretical Energy Potential of Selected Process Residues
Crop | Residue type | Estimated availability factor | Residue[wet t] | Moisture content 1 [%] | Residue[dry t] | Residue 2 energy value [LHV GJ/t] | Residue energypotential [TJ/yr] |
---|---|---|---|---|---|---|---|
Sugar cane | Bagasse | 1 | 613,950 | 48-49 | 316,184 | 12.5 | 3,952 |
Coffee | Husks | 1 | 12,307 | 13 | 10,707 | 12.2 | 131 |
Cashew nut | Shell | 0.17 | 33,167 | 6,5 | 31,012 | 14.9 | 462 |
Tobacco | Stems | unknown | 37,632 | 9 | 34,245 | 12.6 | 431 |
Sisal | Pulp | 1 | 622,800 | 88-94 | 74,736 | 14.4 | 1,076 |
Total | 1,319,857 | 466,884 | 6,053 |
Crop | Residue type | No. of medium to large scale processing sites | Conversion pathways | Expected efficiency | Product | Average energy plant size [MW] |
---|---|---|---|---|---|---|
Sugar cane | Bagasse | 6 | Combustion | 15-25% | Steam, electricity, heat | 8-9 |
Coffee | Husks | 23 | Combustion | 15-25% | Steam, electricity, heat | 0.5-1 |
Briquetting | Solid fuel | |||||
Cashew nut | Husks | 14 | Combustion | 15-25% | Steam, electricity, heat | 0,1-1 |
Tobacco | Stems | unknown | Anaerobic digestion | 25-36% | Biogas, electricity, heat | ___ |
Briquetting | Solid fuel | |||||
Sisal | Pulp | 35 | Anaerobic digestion | 25-36% | Biogas, electricity, heat | 0.1-1 |
3.2. Assessing Environmental Risks and Opportunities
3.2.1. Greenhouse Gas Emissions
3.2.2. Water Use and Water Quality
3.2.3. Biodiversity
Indicator | Sisal | Sugar cane | Coffee | Cashew nut | Tobacco |
---|---|---|---|---|---|
Water use | |||||
Irrigation | None | ✔ (24%) | ✔ (15%) | ✔ (32%) | ✔ |
Water use processing | High | Low | High | Low | Low |
Biodiversity & soil health | |||||
Agricultural area per crop [ha] | 188,131 | 45,000 | 265,000 | 288,520 | 57,438 |
Average area per estate/farm (small & large scale) [ha] | Estate: 34,842 | Estate: 90,000 | Small scale: 0.42Large scale: 71 | Small scale: 1.4Large scale: 97 | Small scale: unknownLarge scale: 256 |
Structure | 10% smallholder90% large scale | 55% smallholder 45% large scale | 89% smallholder 11% estates | 99% smallholder 1% large scale | 90% smallholder 10% large scale |
Number of plants per ha | 3,000-4,000 | ----- | ca. 1,100 | ----- | ----- |
Cultivated area [%] | Total: 3.7 | Total: 1 | Total: 5.3 | Total: 5.8 | Total: 1.2 |
( Regions: Tanga 67; Morogoro 23; Kilimanjaro 6; Mara 4)2 | ( Regions: Morogoro 3; Kilimanjaro 2) | (Regions: Arusha 11, Kilimanjaro 20; Mbeya 10, Ruvuma 9, Kagera 10) | ( Regions: Lindi 12; Mtwara 42, Ruvuma 5) | ( Regions: Tabora 7, Iringa 8) | |
Dominance of non-domesticated species to domesticated species | High in Tanga and Morogoro | ----- | High in Kilimanjaro | High in Mtwara | ----- |
Cultivation mainly in monocultures | ✔ | ✔ | ✔ | no—mostly intercropping | monocultures not dominating |
Use of agricultural pesticides | None | ✔ (High) | ✔ (Very high) | ✔ | ✔ (High) |
Use of inorganic fertilizers | None | ✔ (High) | ✔ (High) | ✔ (Very low) | ✔ (Very high) |
3.2.4. Soil Health
4. Conclusions
Sustainability criteria | Growing and processing | Using residues for energy generation | |
---|---|---|---|
Environmental | Greenhouse gas emissions | - | ++ |
Water use & water quality | -- | + | |
Biodiversity | -- | ||
Soil health | -- | + |
Conflict of Interest
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Terrapon-Pfaff, J.C. Linking Energy- and Land-Use Systems: Energy Potentials and Environmental Risks of Using Agricultural Residues in Tanzania. Sustainability 2012, 4, 278-293. https://doi.org/10.3390/su4030278
Terrapon-Pfaff JC. Linking Energy- and Land-Use Systems: Energy Potentials and Environmental Risks of Using Agricultural Residues in Tanzania. Sustainability. 2012; 4(3):278-293. https://doi.org/10.3390/su4030278
Chicago/Turabian StyleTerrapon-Pfaff, Julia C. 2012. "Linking Energy- and Land-Use Systems: Energy Potentials and Environmental Risks of Using Agricultural Residues in Tanzania" Sustainability 4, no. 3: 278-293. https://doi.org/10.3390/su4030278
APA StyleTerrapon-Pfaff, J. C. (2012). Linking Energy- and Land-Use Systems: Energy Potentials and Environmental Risks of Using Agricultural Residues in Tanzania. Sustainability, 4(3), 278-293. https://doi.org/10.3390/su4030278