Triboelektrostatik Beneficiation daripada Landdiisi lalat Abu WOCA 2015

Triboelectrostatic Beneficiation of

Land Filled Fly Ash

L. Baker, A. Gupta, dan S. Gasiorowski

Peralatan ST & Teknologi LLC, 101 Hampton Avenue, Needham MA 02494 AMERIKA SYARIKAT

CONFERENCE: 2015 World of Coal Ash – (www.worldofcoalash.org)

KATA KUNCI: Triboelectrostatic, Beneficiation, Abu Terbang, Landfilled, Dried, Pemisahan, Carbon

Abstrak

Triboelectrostatic separation has been used for the commercial beneficiation of coal combustion fly ash to produce a low carbon product for use as a cement replacement in concrete for nearly twenty years. With 18 separators in 12 coal-fired power plants across the world, Peralatan ST & Teknologi LLC (STET) patented electrostatic separator has been used to produce over 15 Million tonnes of low carbon product.

To date, commercial beneficiation of fly ash has been performed exclusively on dry “run of station‿ ash. Recent environmental legislation has created, in certain markets, a need to supply beneficiated ash in times of low ash generation. Ini, coupled with a requirement in some locations to empty historical ash landfill sites, has created the need to develop a process to beneficiate historically landfilled ash.

Previous studies have shown that the exposure of fly ash to moisture, and subsequent drying influences the triboelectrostatic charging mechanism, with carbon and mineral particles charging in the opposite polarity to that experienced with run of station ash. Studies have been performed by the authors to determine the effect of moisture exposure on separation efficiency of several ashes that have been reclaimed from landfills and dried. Charge reversal was experienced following drying, but overall separation efficiency was achieved equivalent to that experienced with fresh run of station ash.

The effect of dried ash feed relative humidity on triboelectrostatic separation efficiency was examined, and sensitivity was greatly reduced compared to that experienced with run of station ash, lowering overall process costs.

Pengenalan

The American Coal Ash Association (ACAA) annual survey of production and use of coal fly ash reports that between 1966 Dan 2011, over 2.3 billion short tons of fly ash have been produced by coal-fired utility boilers.1 Of this amount approximately 625 million tons have been beneficially used, mostly for cement and concrete production. Walau bagaimanapun, the remaining 1.7+ billion tons are primarily found in landfills or filled ponded

impoundments. While utilization rates for freshly generated fly ash have increased considerably over recent years, with current rates near 45%, Kira 40 million tons of fly ash continue to be disposed of annually. While utilization rates in Europe have been much higher than in the US, considerable volumes of fly ash have also been stored in landfills and impoundments in some European countries.

Tempahan, interest in recovering this disposed material has increased, partially due to the demand for high-quality fly ash for concrete and cement production during a period of reduced production as coal-fired power generation has decreased in Europe and North America. Concerns about the long-term environmental impact of such landfills are also prompting utilities to find beneficial use applications for this stored ash.

LAND FILLED ASH QUALITY AND REQUIRED BENEFICIATION

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. Since the material has been typically wetted to enable handling and compaction while avoiding airborne dust generation, drying will probably be a minimal requirement for use in concrete since concrete producers will want to continue the practice of batching fly ash as a dry powder. Walau bagaimanapun, 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 utilization has increased in the last 20+ tahun, most “in-spec‿ ash has been beneficially used, and the off-quality ash disposed. Thus, LOI reduction will be a requirement for utilizing the vast majority of fly ash recoverable from utility impoundments.

LOI REDUCTION BY TRIBOELECTRIC SEPARATION

While various workers have used combustion techniques and flotation processes for LOI reduction of recovered landfilled and ponded fly ash, Peralatan ST & Technologies (STET) has found that its standard processing system, long used for beneficiation of freshly generated fly ash, is equally effective on recovered ash after suitable drying and deagglomeration at lower overall operating costs.

During the ramp-up to commercial application of the STET processing system for fly ash, STET researchers tested the separation of dried landfilled ash. This recovered ash separated very similarly to freshly generated ash with one surprising difference: 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 phenomena.3,4,5

TECHNOLOGY OVERVIEW – FLY ASH CARBON SEPARATION

In the STET carbon separator (Rajah 1), material is fed into the thin gap between two parallel planar electrodes. Zarah-zarah dicaj secara triboelektik oleh kenalan interparticle. The positively charged carbon and the negatively charged mineral (in freshly generated ash that has not been wetted and dried) are attracted to opposite electrodes. The particles are then swept up by a continuous moving belt and conveyed in opposite directions. Tali pinggang menggerakkan zarah bersebelahan setiap elektrod ke arah hujung bertentangan pemisah. Kelajuan tali pinggang yang tinggi juga membolehkan kendandahan yang sangat tinggi, selewat-lewatnya 36 tonnes per hour on a single separator. Jurang kecil, high voltage field, aliran semasa kaunter, vigorous particle-particle agitation and self-cleaning action of the belt on the electrodes are the critical features of the STET separator. Dengan mengawal pelbagai parameter proses, seperti kelajuan tali pinggang, titik suapan, dan kadar suapan, proses STET menghasilkan abu terbang LOI rendah pada kandungan karbon kurang daripada 1.5 untuk 4.5% from feed fly ashes ranging in LOI from 4% kepada lebih 25%.

Fig. 1 STET Separator

The separator design is relatively simple and compact. Mesin yang direka untuk memproses 36 tonnes per hour is approximately 9 m (30 Ka.) panjang, 1.5 m (5 Ka.) Luas, Dan 2.75 m (9 Ka.) Tinggi. Tali pinggang dan penggelek yang berkaitan adalah satu-satunya bahagian yang bergerak. Elektrod-elektrod adalah alat tulis dan terdiri daripada bahan tahan lama yang sesuai. The belt is made of non- conductive plastic. The separator’s power consumption is about 1 kilowatt-hour per tonne of material processed with most of the power consumed by two motors driving the belt.

Proses ini sama sekali Kering, 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

Konkrit, and a high carbon fraction useful as fuel. Penggunaan kedua-dua aliran produk menyediakan 100% penyelesaian kepada masalah penjualan Abu Terbang.

RECOVERED FUEL VALUE OF HIGH-CARBON FLY ASH

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 ST Equipment & Technology LLC 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. Utilizing the high carbon EcoTherm™ ash either at a power plant or a cement kiln, maximizes the energy recovery from the delivered coal, reducing the need to mine and transport additional fuel to the facilities.

STET’s Raven Power Brandon Shores, SMEPA R.D. Morrow, NBP Belledune, RWEnpower Didcot, EDF Energy West Burton, and RWEnpower Aberthaw fly ash plants, all include EcoTherm™ Return systems. The essential components of the system are presented in Figure 2.

Fig. 2 EcoTherm™ Return system

STET ASH PROCESING FACILITIES

Controlled low LOI fly ash is produced with STET’s technology at twelve power stations throughout the U.S., Kanada, the U.K., Poland, and Republic of Korea. ProAsh® Abu Terbang telah diluluskan untuk digunakan oleh pihak berkuasa lebuh raya negeri lebih daripada dua puluh, juga kerana banyak agensi spesifikasi. ProAsh® juga telah diperakui di bawah Persatuan piawaian Kanada dan EN 450:2005 standard kualiti di Eropah. Ash kemudahan pemprosesan menggunakan teknologi STET disenaraikan dalam Jadual 1.

Jadual 1. STET Commercial Operations

COAL ASH RECOVERED FROM LAND FILLS

Two sources of ash were obtained from landfills: sample A from a power plant located in

the United Kingdom and sample B: from the United States. Both these samples consisted of ash from the combustion of bituminous coal by large utility boilers. Disebabkan oleh intermingling bahan di tapak pelupusan sampah di, sebarang maklumat lanjut boleh didapati mengenai keadaan sumber atau pembakaran arang batu yang tertentu.

Sampel seperti yang diterima oleh STET terkandung di antara 15% Dan 20% water as is typical for landfilled material. The samples also contained varying amounts of large >1/8 inci (~3 mm) bahan. Untuk menyediakan sampel untuk pengasingan karbon, runtuhan besar adalah dipenuhi dengan pemeriksaan dan sampel kemudiannya dikeringkan dan deagglomerated sebelum beneficiation karbon. Various methods for drying/deagglomeration are being evaluated in order to optimize the overall process. A general process flow sheet is presented in Figure 3.

Rajah 3: Process flow sheet

Hartanah-hartanah sampel disediakan telah baik dalam lingkungan Abu terbang yang diperolehi secara langsung dari dandang biasa utiliti. Sifat-sifat yang paling relevan untuk kedua-dua pemisah suapan dan produk diringkaskan dalam Jadual 2 bersama-sama dengan produk pulih.

PENGASINGAN KARBON

Carbon reduction trials using the STET triboelectric belt separator resulted in very good recovery of low LOI product. The interesting phenomena observed was the reversal of charging of the carbon discussed above. While this behavior has been observed previously by STET and other researchers, the mechanism that changes the relative work functions and thus contact charging behavior of the material is not understood. One suggested mechanism is the redistribution of soluble ions on the mineral and

following table summarizes the chemistry for samples from source B. Testing on source A material has not been completed.

Jadual 4: Ash Chemistry of low LOI ash.

Strength development of a 20% substitution of the low LOI fly ash in a mortar containing 600 lb / yd3 showed the material derived from landfilled ash performed somewhat better than material from fresh production. Lihat Jadual 5 below.

Jadual 5: Compressive strength of mortar cubes.

CONCLUSIONS

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 efficiency of the STET system is essentially equivalent for ashes obtained freshly from boiler operations and dried landfilled material. The separator product is suitable for use in concrete production without further beneficiation with nearly identical performance properties. 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 utilize the process to alter a waste product liability into a valuable raw material for concrete producers.

Rujukan

[1]American Coal Ash Coal Combustion products and Use Statistics: https://www.acaa-usa.org/Publications/Production-Use-Reports/

[2]ST internal report, Ogos 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, Mungkin 19 20, Pittsburgh, PA, 1998.

[4]Baltrus, J.P., Diehl, J.R., Soong, Y., Sands, W. Triboelectrostatic separation of fly ash and charge reversal, Fuel 81, (2002) pp.757-762.

[5]Cangialosi, F., Notarnicola, M., Liberti, L, Stencel, J. The role of weathering on fly ash charge distribution during triboelectrostatic beneficiation, Journal of Hazardous Materials, 164 (2009) pp.683-688.

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