Select Language:
The American Coal Ash Association (ACAA) annual survey of production and use of coal fly ash reports that between 1966 og 2011, Yfir 2.3 billion short tons of fly ash were produced by coal-fired utility boilers. Of this amount, um það bil 625 million tons have been beneficially used, mostly for cement and concrete production. þó, the remaining 1.7+ billion tons are primarily found in landfills or filled ponded impoundments.
Triboelectrostatic Rétthafi urðunar og tjörn Fljúga Ash
By Lewis Baker,Abhishek Gupta, Stephen Gasiorowski, and Frank Hrach
The American Coal Ash Association (ACAA) annual survey of production and use of coal fly ash reports that between 1966 og 2011, Yfir 2.3 billion short tons of fly ash were produced by coal-fired utility boilers.1 Of this amount, um það bil 625 million tons have been beneficially used, mostly for cement and concrete production. þó, the remaining 1.7+ billion tons are primarily found in landfills or filled ponded impoundments. While use rates for freshly generated fly ash have increased considerably over recent years, with current rates near 45%, um það bil 40 million tons of fly ash continue to be disposed of annually. While use rates in Europe have been much higher than in the United States, considerable volumes of fly ash have also been stored in landfills and impoundments in some European countries
Nýverið, áhugi á að endurheimta þetta losaði efni hefur aukist, að hluta til vegna eftirspurnar eftir hágæða Fly Ash fyrir steypu og sementframleiðslu á tímabili með minni framleiðslu sem kol-rekinn máttur kynslóð hefur minnkað í Evrópu og Norður-Ameríku. Áhyggjur af langtímaumhverfisáhrifum slíkra urðunarstaðanna eru einnig tafarlaus tól til að finna gagnleg forrit fyrir þetta geymda Ash.
While some of this stored fly ash may be suitable for beneficial use as initially excavated, the vast majority will require some processing to meet quality standards for cement or concrete production. Because the material has been typically wetted to enable handling and compaction while avoiding airborne dust generation, drying and deagglomeration is a necessary requirement for use in concrete because concrete producers will want to continue the practice of batching fly ash as a dry, fine powder. þó, assuring the chemical composition of the ash meets specifications—most notably the carbon content, measured as loss on ignition (LOI)—is a greater challenge. As fly ash use has increased in the last 20+ Ára, most “in-spec” ash has been beneficially used, and the off-quality ash disposed. Thus, LOI reduction will be a requirement for using the vast majority of fly ash recoverable from utility impoundments.
While other researchers have used combustion techniques and flotation processes for LOI reduction of recovered landfilled and ponded fly ash, ST Equipment & Tækni (STET) has found that its unique triboelectrostatic belt separation system, lengi notað fyrir viðtakendur nýmynduðum fljúgandi Ash, is also effective on recovered ash after suitable drying and deagglomeration.
STET researchers have tested the triboelectrostatic separation behavior of dried landfilled ash from several fly ash landfills in the Americas and Europe. Þessi endurheimti Ash aðskilin mjög álíka að nýmynduðum ösku með einum óvæntan mismun: the particle charging was reversed from that of fresh ash, with the carbon charging negative in relation to the mineral.2 Other researchers of electrostatic separation of fly ash carbon have also observed this phenomenon.3-5 The polarity of the STET triboelectrostatic separator can easily be adjusted to allow rejection of negatively charged carbon from dried landfilled fly ash sources. No special modifications to the separator design or controls are necessary to accommodate his phenomena
Í STET Carbon Skilrúm (Mynd. 1), efni er fóðraður í þunna bilið milli tveggja samsíða planar rafskaut. Þær agnir sem eru mjög hlaðnar með interagnið snertileysi. Hið jákvæða innheimt kolefni og neikvæð innheimt steinefni (í nýmynduðum ösku sem ekki hefur verið bleytt og þurrkuð) eru dregnar saman á móti rafskaut. Agnirnar eru síðan sópaðar upp af samfelldu hreyfanlegum beltum og settar í gagnstæðar áttir. Beltið flytur agnir sem eru samliggjandi við hverja rafall í átt að gagnstæðum endum skiltisins. The high belt speed also enables very high throughputs up to 36 tons per hour on a single separator. Litla bilið, high-voltage field, counter—current flow, vigorous particle-particle agitation, and self-cleaning action of the belt on the electrodes are the critical features of the STET separator. Með því að stýra ýmsum ferlistikum, eins og beltahraði, straumur punktur, og straumhraði, STET ferlið framleiðir lágt LOI fljúga ösku á kolefnisinnihaldi minna en 1.5 að 4.5% from feed fly ashes ranging in LOI from 4% að yfir 25%.
The separator design is relatively simple and compact. Vél hönnuð til vinnslu 40 tons per hour is approximately 30 Ft (9 M) Langur, 5 Ft (1.5 M) wide, og 9 Ft (2.75 M) Hár. Beltið og tengd rollinum eru einu Hreyfðu hlutar. Rafskaut eru kyrrstætt og samsett úr viðeigandi varanlegum efnum. The belt is made of nonconductive plastic. The separator’s power consumption is about 1 kilowatt-hour per ton of material processed with most of the power consumed by two motors driving the belt.
Ferlið er algjörlega þurrt, requires no additional materials other than the fly ash, and produces no waste water or air emissions. The recovered materials consist of fly ash reduced in carbon content to levels suitable for use as a pozzolanic admixture in concrete, and a high-carbon fraction useful as fuel. Use of both product streams provides a 100% lausn til að fljúga aska förgun vandamál.
Four sources of ash were obtained from landfills: Sample A from a power plant located in the United Kingdom and Samples B, C, and D from the United States. All these samples consisted of ash from the combustion of bituminous coal by large utility boilers. Due to the intermingling of material in the landfills, no further information is available concerning specific coal source or combustion conditions.
The samples as received by STET contained between 15 og 27% water, as is typical for landfilled material. The samples also contained varying amounts of large >1/8 í. (3 mm) material. Að undirbúa sýnunum fyrir kolefnisaðskilnað, mikið rusl var fjarlægt með skimun og sýnin síðan þurrkuð og deagglomerated áður en Kolsýringur. Several methods for drying/deagglomeration have been evaluated at the pilot scale to optimize the overall process. STET has selected an industrially proven feed processing system that offers simultaneous drying and deagglomeration necessary for effective electrostatic separation. A general process flowchart is presented in Fig. 2.
The properties of the prepared samples were well within the range of fljúga Ash obtained directly from normal utility boilers. Viðeigandi Eiginleikar fyrir bæði aðgreiningarstrauma og afurðir eru teknar saman í töflu 2, ásamt endurheimtu vöru.
STET separator processing dried, landfilled fly ash
Process flow diagram
Carbon reduction trials using the STET triboelectric belt separator resulted in very good recovery of low-LOI products from all four landfill fly ash sources. The reverse charging of the carbon as discussed previously did not degrade the separation in any way as compared to processing fresh ash.
The properties of the low-LOI fly ash recovered using the STET process for both freshly collected ash from the boiler and ash recovered from the landfill is summarized in Table 1. The results show that the product quality for ProAsh® produced from landfilled material is equivalent to product produced from fresh fly ash sources.
The properties of the ProAsh generated from the reclaimed landfill material were compared to that of ProAsh produced from fresh fly ash generated by the utility boilers from the same location. The processed reclaimed ash meets all the specifications of ASTM C618 and AASHTO M 250 standards. Table 2 summarizes the chemistry for samples from two of the sources showing the insignificant difference between the fresh and reclaimed material.
Styrkja þróun á 20% substitution of the low-LOI fly ash in a mortar containing 600 lb/yd3 cementitious material (see Table 3) showed the ProAsh product derived from landfilled ash yielded mortars with strength comparable to mortars produced using ProAsh from fresh fly ash produced at the same location. The end product of the beneficiated reclaimed ash would support high-end uses in the concrete industry consistent with the highly valuable position ProAsh enjoys in the markets it currently serves.
The availability of low-cost natural gas in the United States greatly enhances the economics of drying processes, including the drying of wetted fly ash from landfills. Table 4 summarizes the fuel costs for operations in the United States for 15% og 20% raki innihald. Dæmigerðar óhagstæðar þurrkarar eru innifaldir í útreiknuðum gildum. Kostnaður miðast við massa efnis eftir þurrkun. The incremental costs for drying fly ash for STET triboelectrostatic separation processing are relatively low.
Even with the addition of feed drying costs, the STET separation process offers a low-cost, industrially proven process for LOI reduction of landfilled fly ash. The STET process for reclaimed fly ash is one-third to one-half of the capital cost compared to combustion-based systems. The STET process for reclaimed fly ash also has significantly lower emissions to the environment compared to combustion or flotation-based systems. Because the only additional air emission source to the standard STET process installation is a natural gas-fired dryer, permitting it would be relatively simple.
| Feed sample to separator | LOI, % | ProAsh LOI, % | ProAsh fineness, % +325 mesh |
ProAsh mass yield, % |
|---|---|---|---|---|
| Fresh A | 10.2 | 3.6 | 23 | 84 |
| Landfilled A | 11.1 | 3.6 | 20 | 80 |
| Fresh B | 5.3 | 2.0 | 13 | 86 |
| Landfilled B | 7.1 | 2.0 | 15 | 65 |
| Fresh C | 4.7 | 2.6 | 16 | 82 |
| Landfilled C | 5.7 | 2.5 | 23 | 72 |
| Landfilled D | 10.8 | 3.0 | 25 | 80 |
| Material source | SiO2 | Al2O3 | Fe2O3 | CaO | MgO | K2O | Na2O | SO3 |
|---|---|---|---|---|---|---|---|---|
| Fresh B | 51.60 | 24.70 | 9.9 | 2.22 | 0.85 | 2.19 | 0.28 | 0.09 |
| Landfilled B | 50.40 | 25.00 | 9.3 | 3.04 | 0.85 | 2.41 | 0.21 | 0.11 |
| Fresh C | 47.7 | 23.4 | 10.8 | 5.6 | 1.0 | 1.9 | 1.1 | 0.03 |
| Landfilled C | 48.5 | 26.5 | 11.5 | 1.8 | 0.86 | 2.39 | 1.18 | 0.02 |
| 7-day compressive strength, % of fresh ash control | 28-day compressive strength, % of fresh ash control | |
|---|---|---|
| Fresh B | 100 | 100 |
| Landfilled B | 107 | 113 |
| Fresh C | 100 | 100 |
| Landfilled C | 97 | 99 |
| Rakt efni, % | Heat requirement KWhr/T wet basis | Drying cost/T dry basis (natural gas cost $3.45/mmBtu) |
| 15 | 165 | $ 2.28 |
| 20 | 217 | $ 3.19 |
In addition to the low-carbon product for use in concrete— brand-named ProAsh—the STET separation process also recovers otherwise wasted unburned carbon in the form of carbon-rich fly ash, branded EcoTherm™. EcoTherm has significant fuel value and can easily be returned to the electric power plant using the STET EcoTherm Return system to reduce the coal use at the plant. When EcoTherm is burned in the utility boiler, the energy from combustion is converted to high-pressure/high-temperature steam and then to electricity at the same efficiency as coal, typically 35%. The conversion of the recovered thermal energy to electricity in the STET EcoTherm Return system is two to three times higher than that of the competitive technology where the energy is recovered as low-grade heat in the form of hot water, which is circulated to the boiler feed water system. EcoTherm is also used as a source of alumina in cement kilns, displacing the more expensive bauxite, which is usually transported long distances. Using the high-carbon EcoTherm ash either at a power plant or a cement kiln maximizes the energy recovery from the delivered coal, draga úr þörfinni til minja og flytja viðbótareldsneyti til aðstæðna.
STET’s Talen Energy Brandon Shores, SMEPA R. D. Morrow, NBP Belledune, RWEnpower Didcot, EDF Energy West Burton, RWEnpower Aberthaw, and the Korea South-East Power fly ash plants all include EcoTherm Return systems.
STET’s separation process has been used commercially since 1995 for fly ash beneficiation and has generated over 20 milljón tonn af hágæða flúoxetín fyrir steypuframleiðslu. Controlled low-LOI ProAsh is currently produced with STET’s technology at 12 orkustöðvar um allt Ísland, Canada, Bretlands, poland, og Lýðveldið Kórea. ProAshfly ash has been approved for use by more than 20 ástand háhyrnu yfirvalda, sem og margar aðrar tilgreiningar stofnana. ProAsh has also been certified under the Canadian Standards Association and EN 450:2005 gæðastöðlum í Evrópu. Ash processing facilities using STET technology are listed in Table 5.
After suitable scalping of large material, drying, and deagglomeration, fly ash recovered from utility plant landfills can be reduced in carbon content using the commercialized STET triboelectric belt separator. The quality of the fly ash product, ProAsh, using the STET system on reclaimed landfill material, is equivalent to ProAsh produced from fresh feed fly ash. The ProAsh product is very well-suited and proven in concrete production. The recovery and beneficiation of landfilled ash will provide a continuing supply of high-quality ash for concrete producers in spite of the reduced production of “fresh” ash as coal-fired utilities reduce generation. Additionally, power plants that need to remove ash from landfills to meet changing environmental regulations will be able to use the process to alter a waste product liability into a valuable raw material for concrete producers. The STET separation process with feed preprocessing equipment for drying and deagglomerating landfilled fly ash is an attractive option for ash beneficiation with significantly lower cost and lower emissions compared to other combustion- and flotation-based systems. ❖
1. American Coal Ash Coal Combustion Products and Use Statistics, http://www.acaausa.org/Publications/Production-Use-Reports.
2. ST Internal Report, Ágú. 1995.
3. Li, T. X.; Schaefer, J. L.; Ban, H.; Neathery, J. K.; and Stencel, J. M., “Dry Beneficiation Processing of Combustion Fly Ash,” Proceedings of the DOE Conference on Unburned Carbon on Utility Fly Ash, Pittsburgh, PA, maí 19-20, 1998.
4. Baltrus, J. P.; Diehl, J. R.; Soong, Y.; and Sands, W., “Triboelectrostatic Separation of Fly Ash and Charge Reversal,” Fuel, V. 81, 2002, Pp. 757-762.
5. Cangialosi, F.; Notarnicola, M.; Liberti, L.; and Stencel, J., “The Role of Weathering on Fly Ash Charge Distribution during Triboelectrostatic Beneficiation,” Journal of Hazardous Materials, V. 164, 2009, Pp. 683-688.
Lewis Baker is the European Technical Support Manager for ST Equipment & tækni (STET) based in the United Kingdom
Abhishek Gupta is a Process Engineer based at the STET pilot plant and lab facility in Needham, MA.
Stephen Gasiorowski is a Senior Research Scientist for ST Equipment & tækni (STET) based in New Hampshire.
Frank Hrach is Vice President of Process Engineering based at the STET pilot plant and lab facility in Needham, MA.
| Utility and power station | Staðsetning | Upphaf atvinnustarfsemi | Upplýsingar um aðstöðu |
|---|---|---|---|
| Duke Energy—Roxboro Station | North Carolina | Sept. 1997 | 2 separators |
| Talen Energy—Brandon Shores Station | Maryland | Apr. 1999 | 2 separators 35,000 ton storage dome Ecotherm Return 2008 |
| ScotAsh (Lafarge / Scottish Power Joint Venture)—Longannet Station | Scotland, Bretlandi | október. 2002 | 1 Skiltákn |
| Jacksonville Electric Authority— St. John’s River Power Park, FL | Florida | maí 2003 | 2 separators Coal/petcoke blends Ammonia removal |
| South Mississippi Electric Power Authority R.D. Morrow Station | Mississippi | Jan. 2005 | 1 separator Ecotherm return |
| New Brunswick Power Company Belledune Station | New Brunswick, Canada | Apr. 2005 | 1 separator Coal/petcoke blends Ecotherm return |
| RWE npower Didcot Station | England, U | Ágú. 2005 | 1 separator Ecotherm return |
| Talen Energy Brunner Island Station | Pennsylvania | Dec. 2006 | 2 separators 40,000 ton storage dome |
| Tampa Electric Co. Big Bend Station | Florida | Apr. 2008 | 3 separators, tvöfaldur passi 25,000 ton storage dome Ammonia removal |
| RWE npower Aberthaw Station (Lafarge Cement UK) | Wales, Bretlandi | Sept. 2008 | 1 separator Ammonia removal Ecotherm return |
| EDF Energy West Burton Station (Lafarge Cement UK, Cemex) | England, Bretlandi | október. 2008 | 1 separator Ecotherm return |
| ZGP (Lafarge Sement Pólland / Ciech Janikosoda JV) | poland | Spilla. 2010 | 1 separato |
| Korea South-East Power Yeongheung Units 5&6 | Suður-Kórea | Sept. 2014 | 1 separator Ecotherm return |
| PGNiG Termika-Siekierki | poland | Áætluð 2016 | 1 separator Ecotherm return |
| To Be Announced | poland | Áætluð 2016 | 1 separator Ecotherm return |
