Bond work index equation
test work. Bond work indices, obtained from bench-scale or pilot- plant crushability and grindability tests are used in the fol- lowing Bond equation (Bond , 1960) Oct 20, 2015 The Bond work index – so crucial to comminution planning become engineering practice which was based on measurement and calculation. The Bond Ball Mill Work Index is a measure of the resistance of the material to grinding in a ball mill. It can be used to determine the grinding power required for Fur- thermore, the grinding kinetics and mass balance equations were applied to model the standard Bond Keywords: rod-mill work index. For comparing the As a fast method, the determination of the Bond index from the Hardgrove index ( by calculation) is almost matching with measured Bond's work index.
Bond Work Index Formula-Equation - Mineral Processing & Extractive Metallurgy - Free download as PDF File (.pdf), Text File (.txt) or read online for free. work index
Bond Work Index Tests. Grinding Solutions offers a range of Bond Work Index Testing from crushability and abrasion to ball and rod mills. For more information on the tests please see below: Bond Low Energy Impact Test. The Bond Low-Energy Impact test can be used to determine the Crusher Work index (CWi), also known as the Impact Work Index. Abstract: The Bond work index is a measure of ore resistance to crushing and grinding and is determined using the Bond grindability test. Its value constitutes ore characteristic and is used for industrial comminution plants designing. Determining the Bond work index value is quite complicated, time- The total return for the bond index fund as a whole is simply the average return* of each rung specified for the fund. (*) Real-world bond index funds also weight the rungs according to the market size of each bond issue, and unfortunately this market weighting data is extremely difficult to find. Bond Work Index Formula-Equation Basic EquationsSize Distribution and Exposure RatioEquations For Work Index VariationsWork Index and Crack Energy The basic work index equation is:W = 10 Wi/√P – 10 Wi/√F(1)where W is the work input required in kilowatt hours per short ton to grind from 80% passing F microns to 80% passing P microns, and Wi is the work index, or the grinding resistance Bond Work Index Formula-Equation Basic EquationsSize Distribution and Exposure RatioEquations For Work Index VariationsWork Index and Crack Energy The basic work index equation is:W = 10 Wi/√P – 10 Wi/√F(1)where W is the work input required in kilowatt hours per short ton to grind from 80% passing F microns to 80% passing P microns, and Wi is the work index, or the grinding resistance 1, according to Bond [2] n = 0.5 and according to Charles [3] and Stamboliadis [4], n. can take any value near these two. In the case that the initial size is infinite and the final size is 100 μm then by definition the required specific energy is called work index . W. i ,100 e W. i (2) The value of the constant . C. in (1) can be calculated Bond Work Index Tests. Grinding Solutions offers a range of Bond Work Index Testing from crushability and abrasion to ball and rod mills. For more information on the tests please see below: Bond Low Energy Impact Test. The Bond Low-Energy Impact test can be used to determine the Crusher Work index (CWi), also known as the Impact Work Index.
using Bond's formula with the reference work index of 11.25 kW/STPH. accurate values of sodium feldspar's work indices, the time-consuming Bond procedure
Bond Work Index Formula-Equation Basic EquationsSize Distribution and Exposure RatioEquations For Work Index VariationsWork Index and Crack Energy The basic work index equation is:W = 10 Wi/√P – 10 Wi/√F(1)where W is the work input required in kilowatt hours per short ton to grind from 80% passing F microns to 80% passing P microns, and Wi is the work index, or the grinding resistance 1, according to Bond [2] n = 0.5 and according to Charles [3] and Stamboliadis [4], n. can take any value near these two. In the case that the initial size is infinite and the final size is 100 μm then by definition the required specific energy is called work index . W. i ,100 e W. i (2) The value of the constant . C. in (1) can be calculated
Bond work index (in kilowatt hours per metric ton ore),. 3 a constant for any product discard size, is calculated from the following Bond-derived (5) equation: W.
1, according to Bond [2] n = 0.5 and according to Charles [3] and Stamboliadis [4], n. can take any value near these two. In the case that the initial size is infinite and the final size is 100 μm then by definition the required specific energy is called work index . W. i ,100 e W. i (2) The value of the constant . C. in (1) can be calculated Bond Work Index Tests. Grinding Solutions offers a range of Bond Work Index Testing from crushability and abrasion to ball and rod mills. For more information on the tests please see below: Bond Low Energy Impact Test. The Bond Low-Energy Impact test can be used to determine the Crusher Work index (CWi), also known as the Impact Work Index. Where Kb is a constant that depends on the type of machine and on the material being crushed. To use this equation, a work index Wi is defined as the gross energy requirement in kilowatt-hours per ton of feed needed to reduce a very large feed to such a size that 80% of the product passes a 100-µm screen. Bond Grinding Circuit Efficiency Meeting of Bond Efficiency Guideline Working Group of the Global Mining and Standards Group Salt lake City, 2014 Based on Presentation to the 2008 Meeting of SME, by C.A. Rowland, Jr. and R.E. McIvor. Bond Grinding Circuit Efficiency • The Bond Work Index equation • Ore test WI • Circuit operating WI Bond valuation is a technique for determining the theoretical fair value of a particular bond. Bond valuation includes calculating the present value of the bond's future interest payments, also
grinding cycles. The Bond Work Index is calculated using the formula: 𝑖=1,1 44,5 𝑃𝑐 0,23𝐺,82(10 √𝑃80 −10 √𝐹80) (1) where W i – Bond work index (kWh/t) P c – test sieve mesh size (µm) G – weight of the test sieve fresh undersize per mill revolution (g/rev) F 80 – sieve mesh size passing 80% of the feed before grinding(µm) P 80
The work index is computed using the following empirical equation revised by Bond in 1960, where the sieve opening at which the test is made, (microns). 358. Feb 5, 2015 with work index of 15.13kwh/ short ton was used to calculate the work index KEYWORDS: Bond's index, Arufu Lead Ore, modified, reference The basic work index equation is: W = 10 Wi/√P – 10 Wi/√F…………………………………………………………………………(1) where W is the work input required in kilowatt hours per short ton to grind from 80% passing F microns to 80% passing P microns, and Wi is the work index, or the grinding resistance parameter. The most widely used parameter to measure ore hardness is the Bond work index Wi. Calculations involving Bond’s work index are generally divided into steps with a different Wi determination for each size class. The low energy crushing work index laboratory test is conducted on ore specimens larger than 50 mm, determining the crushing work index (Wi C, CWi or IWi (impact work index)).
Bond Work Index Formula-Equation - Mineral Processing & Extractive Metallurgy - Free download as PDF File (.pdf), Text File (.txt) or read online for free. work index Bond Work Index Equation is: 𝑾= 𝑾𝒊 𝑷𝟖 − 𝟖 Where W is the work input (kWh/t), W i is the Work Index (kWh/t), and F 80 and P 80 are the 80% passing size of the feed and product (µm) respectively. Bond Work Index W i can be found through the following equation: 𝑾𝒊= . 𝑷 . .𝟖 grinding cycles. The Bond Work Index is calculated using the formula: 𝑖=1,1 44,5 𝑃𝑐 0,23𝐺,82(10 √𝑃80 −10 √𝐹80) (1) where W i – Bond work index (kWh/t) P c – test sieve mesh size (µm) G – weight of the test sieve fresh undersize per mill revolution (g/rev) F 80 – sieve mesh size passing 80% of the feed before grinding(µm) P 80 The Bond work index is a measure of ore resistance to crushing and grinding and is determined using the Bond grindability test. Its value constitutes ore characteristic and is used for industrial comminution plants designing. Determining the Bond work index value is quite Bond Work Index. In the 1930s through early 1950s, Bond developed a new theory of comminution that introduced an index, called the 'Bond Work Index', which relates power consumption in crushing and grinding to the feed and product size distribution. His theory and index were introduced in a widely cited 1952 journal article. Hence, the price of the bond calculation using the above formula as, Bond price Equation = $104,158.30 Since the coupon rate is higher than the YTM, the bond price is higher than the face value and as such, the bond is said to be traded at a premium.