Cut-off grade estimation

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Cut-Off grade is the minimum amount of valuable mineral in a given mining unit required to mine (or process) at a profit. Material above this grade is considered to be ore, and material below this grade is considered to be waste. g/t % $/t Usually expressed as:


== [[1.0 Calculating the Cut-Off Grade 1]] 1.1 Break-Even and Internal 1 1.2 Lane’s Method 2 1.3 Equivalent Grade 3 2.0 Mineral Classification 4 2.1 Grade-Tonnage Curves 4 3.0 Adjusting the Cut-Off Grade 5 ==

[[== 1.0 Calculating the Cut-Off Grade ==]]

== 1.1 Break-Even and Internal

The most simplistic way to determine cut-off grade utilizes the following formula: Equation 1. G=(c+m_o-m_w)/(y(s-r)) Table 1: Basic Cut-Off Grade Parameters mo cost to mine ore mw cost to mine waste r refinery unit cost c cost to process ore y metal recovery s unit metal sale price

For the Internal (Milling) cut-off grade, mw = mo. This is simplified in Equation 2. Material below this grade should not be processed whether or not it has already been mined. G_Mill=c/(y(s-r)) For the Break-even (Mining) cut-off grade, mw = 0. This is simplified in Equation 3. Material below this grade should not be mined. G_Mine=(c+m_o)/(y(s-r))

These cut-off grades are the fastest way to classify ore and waste, however, in a more detailed analysis they should not be relied on.

1.2 Lane’s Method

Lane’s Method offers a more accurate and complex way to calculate cut-off grade. This method also requires more information, so it may not be the first choice for a preliminary calculation. Although there are many intermediate grades determined through Lane’s Method, there is ultimately only one output cut-off grade.

Table 2: Lane’s Method Cut-Off Grade Parameters y Recovery C Concentrator capacity R Refining capacity f Fixed costs s Sale price c Concentrator costs r Refining costs V Present value d Discount rate



gmc = f(Qm,Qc,gradedistribution) grc = f(Qr,Qc,gradedistribution) gmr = f(Qm,Qr,gradedistribution) Qm Mine capacity Qc Concentrator capacity Qr Refining capacity

1.3 Equivalent Grade The following formula can be used to classify the equivalent grade for a mining unit: G = g1 + f2g2 + f3g3 + …

Failed to parse (syntax error): {\displaystyle G = g1 + f2g2 + f3g3 + …} This is necessary for polymetallic deposits in which the value of a block may be influenced by more than one valuable mineral. It simplifies the value of the block so that cut-off grade analysis can be performed, and a decision of whether or not to mine the block can be made.

2.0 Mineral Classification

Cut-off grades are used to determine the point at which material becomes economically valuable. Therefore, they are necessary to define the amount of ore in a deposit. The classification of ore depends entirely on cut-off grade. Increasing the cut-off grade places a stricter requirement on what can be considered ore. This decreases the amount of material that can be considered ore, and with it the reserves and life of mine.

2.1 Grade-Tonnage Curves

Grade-Tonnage curves are a visual representation of the impact of cut-off grades on mineral reserves. Example.jpg

Figure 1: An Example Grade-Tonnage curve (J.M. Rendu) Metal value is not the only factor affecting the profitability of a block. The presence of unwanted (often hazardous) material in a block may increase the processing cost [SME reference]

3.0 Adjusting the Cut-Off Grade

Stockpiling and blending are often used to ensure consistency of mill feed. This can affect cut-off grade since If the metal price increases, it may seem intuitive to lower the cut-off grade since the low grade material can be mined at a profit. However, the better decision is often to increase the cut-off grade instead. Processing the higher grade material will yield an increase in the amount of valuable mineral produced. This is assuming that the processing capacity does not change; only the ore being processed does. The extra product can then be sold at this increased price.

Extraction Sequence and Variable Grade Interprocess Options

  • Polymetallic Deposits & Metal Equivalencies

Selectivity and Dilution Constraints Stock Piling and Pushback Factors Opportunity Costs, Discount Rates, and NPV Equation 1: Interprocess Options

In the case of multiple processing options U1G1 = U2G2 utility This means that if process A is cheaper than process B, the cut-off grade for process A