• Title/Summary/Keyword: Hardgrove Grindability Index

Search Result 4, Processing Time 0.018 seconds

Property of the Jurassic anthracite (Anthracite from the Seongju Area of the Chungnam Coalfield) (충남탄전(忠南炭田) 무연탄(無煙炭)의 특성(特性))

  • Park, Suk Whan;Park, Hong Soo
    • Economic and Environmental Geology
    • /
    • v.22 no.2
    • /
    • pp.129-139
    • /
    • 1989
  • The anthracite coalfields of Korea are confined to the areas where sedimentary rocks of Permian and Jurassic are preserved. The Chungnam coalfield lies in the sedimentary rocks of Jurassic which belongs to the Daedong Supergroup (the Nampo group). For the property analysis of each coal seam interbeded in Daedong Supergroup, Seongju area is chosen and twelve coalseams are taken. Many standard tests have been established for optical analysis (maceral analysis, coalification degree measurement), chemical analysis (proximate, ultimate analysis) and physical analysis (ignition temperature, ash fusion temperature, hardgrove grindability index and X-ray diffraction). The Jurassic anthracite mainly consist of vitrinite and macrinite and the range of the reflectance is $R_{max}$ 5.0-6.5 which means metaanthracite rank. By the chemical composition analysis, it shows low H/C and high O/C value compare with international average value. By the physical analysis, it has very high ignition temperature ($531-584^{\circ}C$) and ash fusion temperature ($1510-1700^{\circ}C$) and very low combustion velocity (0.2-1.9 mg/min). The very wide range of the hardgrove grindability index (46-132) means that the grindability controlled mainly by the structural conditions of coal bearing strata.

  • PDF

Applicability of Various Biomasses to Pulverized Coal Power Plants in Terms of their Grindability (다양한 바이오매스의 분쇄도 실험을 통한 미분탄 화력발전 적용가능성 연구)

  • Kang, Byeol;Lee, Yongwoon;Ryu, Changkook;Yang, Won
    • Clean Technology
    • /
    • v.23 no.1
    • /
    • pp.73-79
    • /
    • 2017
  • Recently usage of biomass is increased in pulverized coal power plants for reduction of $CO_2$ emission. Many problems arise when thermal share of the biomass is increased, and milling of the biomasses is one of the most important problems due to their low grindability when existing coal pulverizer is used. Grindability of coal can be measured through the HGI (Hardgrove grindability index) equipment as a standard, but method of measuring biomass grindability has not been established yet. In this study, grinding experiment of coal and biomass was performed using a lab-scale ball mill. One type of coal (Adaro coal) and six biomasses (wood pellet (WP), empty fruit bunch (EFB), palm kernel shell (PKS), walnut shell (WS), torrefied wood chip (TBC) and torrefied wood pellet (TWP)) were used in the experiment. Particle size distributions of the fuels were measured after being milled in various pulverization times. Pulverization characteristics were evaluated by portion of particles under the diameter of $75{\mu}m$. As a result, about 70% of the TBC and TWP were observed to be pulverized to sizes of under $75{\mu}m$, which implies that they can be used as alternative biomass fuels without modification of the existing mill. Other biomass was observed to have low grindability compared with torrefied biomass. Power consumption of the mill for various fuels was measured as well, and the results show that lower power was consumed for torrefied biomasses. This result can be used for characterization of biomass as an alternative fuel for pulverized coal power plants.

Torrefaction Effect on the Grindability Properties of Several Torrefied Biomasses

  • Setyawan, Daru;Yoo, Jiho;Kim, Sangdo;Choi, Hokyung;Rhim, Youngjoon;Lim, Jeonghwan;Lee, Sihyun;Chun, Dong Hyuk
    • Korean Chemical Engineering Research
    • /
    • v.56 no.4
    • /
    • pp.547-554
    • /
    • 2018
  • Torrefaction is the promising process of pretreating biomass materials to increase the quality of their energy, especially to upgrade the materials' grindability so that it is suitable for a commercial pulverizer machine. In this study, torrefaction of oak, bamboo, oil palm trunk, and rice husk was carried out under different torrefaction temperatures ($300^{\circ}C$, $330^{\circ}C$, and $350^{\circ}C$) and different torrefaction residence times (30, 45, and 60 minutes). Complete characterization of the torrefied biomass, including proximate analysis, calorific value, thermogravimetric analysis, mass yield, energy yield, and grindability properties (Hardgrove Grindability Index) was carried out. Increasing the torrefaction temperature and residence time significantly improved the calorific value, energy density (by reducing the product mass), and grindability of the product. Furthermore, for commercial purposes, the torrefaction conditions that produced the desired grindability properties of the torrefied product were $330^{\circ}C-30minutes$ and $300^{\circ}-45minutes$, and the latter condition produced a higher energy yield for bamboo, oil palm trunk, and rice husk; however, torrefaction of oak did not achieve the targeted grindability property values.

Evaluation and application of grinding index of domestic desulfurization limestone (국내 탈황용 석회석의 분쇄성 지수 평가 및 응용)

  • Seo, Jun Hyung;Baek, Chul Seoung;Cho, Jin Sang;Ahn, Young Jun;Ahn, Ji Whan;Cho, Kye Hong
    • Journal of Energy Engineering
    • /
    • v.28 no.1
    • /
    • pp.1-9
    • /
    • 2019
  • In the flue gas desulfurization process of the coal-fired power plant, the grinding efficiencies of the limestone as the sorbent for desulfurization were compared after BWI and HGI measurements. As a result, the grinding index of the domestic desulfurization limestone were linear inversely proportional relationship with decreasing BWI was observed with increasing HGI. There was a difference in grinding efficiency depending on the chemical composition and crystal structure. Therefore, it is considered that when grinding ability of limestone is measured, the grinding property of the sample can be confirmed even by using HGI which can be measured more easily than BWI which is difficult to measure and takes a long time. The desulfurization efficiency can be improved by selective utilization of limestone depending on the crushing characteristics.