A Study on the Hard Coal Grindability Dependence on Selected Parameters

A very important aspect of proper preparation of the coal mixture for the coking process is its appropriate grinding. One of the parameters describing the energy input required for grinding is the Hardgrove index. This research was undertaken to determine the dependence of the Hardgrove grindability index on selected physicochemical properties of coal. The Hardgrove grindability index was determined using the available methods described in the standards, and the dependence on selected parameters was examined. A clear positive correlation with calorific value and smaller (also positive) correlations with moisture content and free swelling index was obtained. A slight negative correlation was also obtained with sulfur content.

Evaluation of the Potential of Agricultural Waste Recovery: Energy Densification as a Factor for Residual Biomass Logistics Optimization

The use of residual forms of biomass, resulting from processes of transformation of the agri-food and/or forest industries, presents itself as an alternative with high potential for energy recovery, given the existing availability, both from the perspective of quantities, but also from the perspective of geographic distribution. In this work, samples of four by-products originating from the agri-food industry were collected, namely coconut shells, sugarcane bagasse, cashew nutshells, and palm kernel shells, which were characterized in the laboratory by determining their Thermogravimetric and Elemental analysis, subsequently calculating the High Heating Value, Low Heating Value, Hardgrove Grindability Index, Mass Yield, Energy Yield, and Energy Densification Ratio. The values obtained show the potential to optimize logistical operations related to transportation, demonstrating that energy densification operations, especially if associated with physical densification processes, enable the use of these residual forms of biomass in the replacement of fossil fuels, such as coal.

IDENTIFIKASI KEBERADAAN LOGAM TANAH JARANG (LTJ) PADA TAILING TIMAH MENGGUNAKAN ALAT XRF PORTABLE DAN XRF MAX/PORTRACE-KECAMATAN MERAWANG

Penelitian ini dilakukan di Kecamatan Merawang, Kabupaten Bangka dengan sampel pasir hasil tailing timah sebagai bahan uji dalam mengaplikasikan penerapan dua instrument (alat) yaitu alat X-Ray Fluorescence (XRF) Portable dan X-Ray Fluorescence (XRF) Max/Portrace dalam mengetahui unsur mineral logam tanah jarang. Metode penelitian diawali dengan pencucian sampel pasir untuk menghilangkan kotoran yang menempel di butiran pasir lalu dilakukan pengeringan, pengecilan ukuran butir dari sampel pasir dengan Hardgrove Grindability Index (HGI) dan kemudian dilakukan pengayakan menggunakan Sieve Shaker dengan ukuran 60,80,120,200 dan –200 mesh. Analisis yang digunakan untuk mengidetifikasi keberadaan logam tanha jarang menggunakan sampel pasir under size (-200mesh). Hasil pengujian dari kedua alat tersebut dapat mengidentikasi unsur mineral sebanyak 44 mineral untuk X-Ray Fluorescence (XRF) Max/Portrace sedangkan alat X-Ray Fluorescence (XRF) Portable sebanyak 11 unsur mineral. Berdasarkan pengujian sampel pasir pada alat XRF Portable dan XRF Max/Portrace menunjukkan unsur mineral Sn teridentifikasi lebih banyak terutama pada SP-2 sebesar 3200 ppm. Uji XRF Max/Portrace lebih dominan mendeteksi mineral Sn sedangkan pada unsur mineral Ti lebih dominan teridentifikasi pada alat XRF Portable terutama pada sampel SP-2 sebesar 865 ppm. Penggunaan XRF Portable lebih efektif jika digunakan untuk mengidentifikasi awal keberadaan kandungan Sn yang terdapat pada sampel pasir. Kata-kata kunci: Tailing timah, XRF, logam tanah jarang

Torrefied Biomass as an Alternative in Coal-Fueled Power Plants: A Case Study on Grindability of Agroforestry Waste Forms

The use of biomass as a renewable energy source is currently a reality, mainly due to the role it can play in replacing fossil energy sources. Within this possibility, coal substitution in the production of electric energy presents itself as a strong alternative with high potential, mostly due to the possibility of contributing to the decarbonization of energy production while, at the same time, contributing to the circularization of energy generation processes. This can be achieved through the use of biomass waste forms, which have undergone a process of improving their properties, such as torrefaction. However, for this to be viable, it is necessary that the biomass has a set of characteristics similar to those of coal, such that its use may occur in previously installed systems. In particular, with respect to grindability, which is associated with one of the core equipment technologies of coal-fired power plants—the coal mill. The objective of the present study is to determine the potential of certain residues with agroforestry origins as a replacement for coal in power generation by using empirical methods. Selected materials—namely, almond shells, kiwifruit pruning, vine pruning, olive pomace, pine woodchips, and eucalyptus woodchips—are characterized in this regard. The materials were characterized in the laboratory and submitted to a torrefaction process at 300 °C. Then, the Statistical Grindability Index and the Hardgrove Grindability Index were determined, using empirical methods derived from coal analysis. The results obtained indicate the good potential of the studied biomasses for use in large-scale torrefaction processes and as replacements for coal in the generation of electrical energy. However, further tests are still needed, particularly relating to the definition of the ideal parameters of the torrefaction process, in order to optimize the grindability of the materials.

PETROGRAFI DAN GEOKIMIA BATUBARA DI DAERAH PAHIRANGAN DAN SEKITARNYA, KABUPATEN KOTAWARINGIN TIMUR, PROVINSI KALIMANTAN TENGAH

Komposisi maseral dan mineral serta peringkat batubara merupakan beberapa parameter yang digunakan untuk penentuan karakteristik batubara. Penelitian di daerah Pahirangan dan sekitarnya bertujuan mengetahui karakteristik batubara Formasi Dahor berupa komposisi maseral dan mineral serta peringkat batubara. Komposisi maseral dan mineral dilakukan dengan analisis petrografi untuk mengetahui material organik pembentuk batubara, sementara identifikasi peringkat batubara dilakukan dengan analisis geokimia dan pengukuran reflektansi vitrinit. Analisis dilakukan tehadap 42 conto di Formasi Dahor. Komposisi kelompok maseral utama didominasi oleh huminit yang berkisar antara 64,40% s.d. 93,60% dan sebagian kecil inertinit (2,00% s.d. 20,40%) serta liptinit (0,00% s.d. 10,00%). Berdasarkan parameter hasil perhitungan, nilai reflektansi vitrinit, kandungan air, Hardgrove Grindability Index, unsur hidrogen, oksigen, dan karbon mengindikasikan batubara di daerah penelitian termasuk dalam peringkat lignit-subbituminus, sedangkan material organik pembentuk batubara berasal dari tumbuhan berkayu.

Practical assessment of grinding capacity and power consumption based on Hardgrove grindability index and coal characteristics

This paper analyzes the effects of coal grindability and its characteristics on the grinding capacity and power consumption for beater wheel mill during exploitation in thermal power plant TENT B in Obrenovac, Serbia. For this purpose, experiments were made on the mill, before and after its reconstruction. Experiments included the determination of grinding capacity, mill power consumption, and laboratory analysis of coal characteristics and Hardgrove grindability index (HGI). The analysis of experimental results found that the grinding capacity has a negative correlation with the ash content in coal. Moisture content in analysis sample of coal has a positive correlation with the consumption of electricity and grinding capacity. Between the grinding capacity and the value of HGI exists a negative correlation. Analysis of the influence of grindability of coal and coal characteristics on grinding capacity and energy consumption was carried out. Based on coal characteristics and values of HGI, mathematical expressions were derived for the calculation of grinding capacity and electric energy consumption. In addition, ability to predict specific power consumption of the mill on the basis of HGI values, were carried out. Specific power consumption obtained from HGI values showed good agreement with the experimentally determined specific power consumption of the mill.