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Fire assaying

Charles Jojo Besitan
Charles Jojo Besitan

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Fire Assaying
A. Definition and Scope Assaying is the process of determining the proportion of metals in ores and metallurgical products. There has been a tendency to restrict the term to fire methods for the determination of metals so that wet chemical analytical procedures and spectrographic methods of analysis are usually termed “analysis” instead of “assaying”.
Fire Assaying is a branch of quantitative chemical analysis where metals are determined in ores and metallurgical products with the aid of heat and dry reagents.
Fire assaying is carried out today as much as they were then. This ancient method is still taught in university courses for metallurgist because it offers a convenient way of studying the reaction of igneous chemistry. It is still used in the industries, mining and refineries, because modern science has been unable to develop better methods of determining precious-metal content of ores. This is because, large samples can be economically and accurately assayed by fire method but spectrographic method of analysis are not adopted to operating on large sample portions, while wet chemical method, involving digestion of large samples would be very expensive.
The fire assay method is generally applied to gold, silver and some metals in the platinum group. The fire assay of gold and silver depends mainly upon: a. High solubility of these metals in molten metallic lead and their almost complete insolubility in slag. b. The difference in specific gravity between the two liquids, lead and slag, which permits the complete separation of precious metal-bearing lead from the slag. c. Complete removal of lead (Pb) from the previous metals by controlled oxidizing fusion involving differential filtration, in a porous vessel known as cupel. d. The solubility of silver and complete insolubility of gold in dilute nitric acid.
B. Objectives of Assaying 1. Valuation of mining property. 2. Basis of buying and selling ores and metallurgical products. 3. Guide to prospecting and development of ore bodies. 4. Delimitation of boundaries of marginal ores.
5. Check against dilution in mining operation. 6. Control of average grade of ore mined and milled. 7. Investigation and control of metallurgical process. 8. Accounting of all metals in process.
C. Degree of accuracy required in assaying depends upon which of the above purposes is involved. Highest degree of accuracy on individual sample is necessary in buying and selling ores and metallurgical products, so average of 2 to 3 determinations is a must. If parties do not agree a duplicate pulp is submitted to umpire who reports average of four or more determinations. Samples for mine valuation will need rigid precautions to avoid contamination or accidental salting.
Mill tailings and smelter slags require special care since small error will seriously affect the metallurgical balance. Other purposes of assaying as outlined above do not generally require a high degree of precision, single determination with ordinary precaution against errors are usually adequate.
D. Unit in Fire Assaying In the USA, Canada and South Africa, the assay of precious metals is expressed as troy ounces per short ton (2000 avoirdupois pound) of ore. A system of assay ton weighs is used in weighing the assay portion of ore, which is taken for assay process. The assay-ton contains the same number of milligrams (29,166), as there are troy ounces in a short ton. Hence, the number of milligrams of precious metal found in an assay-ton of ore indicates the assay in troy ounces per short ton.
In the Philippines and other countries including the countries mentioned above who used or shifted to metric system. The proportion of precious metals is reported in grams per metric ton of ore. The metric ton contains 1,000,000 grams; consequently one (1) milligram of gold from a 10-grams assay sample or ore indicates 100 grams per metric ton of ore.
E. Requirements in Fire Assaying
1. Apparatus 1. Muffle Furnace - oil fired or electric furnace 2. Balance and Weights - should be sensitive to 0.005 mg at least. It need not have a capacity of more than 1,000 g but should be accurate with that load. 3. Cupels - a flat, shallow crucible of bone ash, used in cupellation. 4. Fusion Crucible - 20 g capacity 5. Iron Mould 6. Annealing Crucible – 10 g Coors porcelain crucible. 7. Hot plate
2. Reagents A flux is a substance which when heated in contact with some difficulty fusible compounds either combines in it or takes it into solution, in each case producing a compound or mixture which is easily fusible at ordinary furnace temperatures. The principle fluxes and other reagents used in fire assaying are the following:
1)Borax and Borax Glass – these are active and readily fusible acid fluxes. These lower the temperature of slag formation and are considered excellent solvent for metallic oxides. These are used as cover to prevent loss of ore which results from the escape of gas at a temperature below that incipient fusion. 2)Silica – acid reagent which combines with metal oxides to form the slag, protects crucible from corrosion. 3)Litharge – basic reagent and aids in the fusion of acid substance. When reduced, it supplies the lead for the button.
4)Soda Ash – basic flux and when molten is very fluid and holds in suspension finely ground infusible materials. To some extent, it reacts with the metallic sulfides to form alkaline sulfide and sulfates. 5)Flour – powerful reducing agent and reduces litharge to lead for the collection of gold and silver. 6)Niter – this is a powerful oxidizing agent. It oxidizes sulfides, arsenides, antimonides. It is used to control the size of the button when the reducing agent effect of the charge is high.
F. Process Terminology Involved 1. Sampling – grinding sample too fine a mesh should be avoided, 80-120 mesh is probably the best range. 2. Fusion – melting together of the fluxes and the sample at 1,000°C. Time ranges from 40-50 minutes. A long-continued fusion at low temperature means a small lead button (ideal weight is 23-30 g), and an imperfect collection of gold and silver. Pouring melt in molds separates lead buttons which are hammered in rough cubes. 3. Cupellation – the separation of gold and silver in a cupel, wherein the impurities are volatilized or absorbed by the cupel, and a button of noble metal known as dore (an alloy of gold and silver left after cupellation) is left. Pre-heat the cupel in the furnace for at least 20 minutes. Starting temperature is ideal at 900°C.
4. Parting – the separation of gold from silver by dissolution with dilute nitric acid. 5. Annealing – tempering by heating, then cooling, to render the gold less brittle. 6. Weighing – values may sometimes be nil (not visible) or trace (visible but negligible in weight). 7. Inquartation – addition of inquartz with known Ag content.
G. Procedure 1. After drying the sample, stage-crush to minus 1.82 mm and reduce by a series of crushing, mixing and cutting until the desired amount of approximately 300 grams is obtained for pulverizing to minus 100 mesh. 2. Mix the sample thoroughly by rolling in a rubber cloth and scoop sample at random for weighing. Normally 10, 15, 20 or 30 grams is used depending on the grade of the precious metal. 3. Add the necessary fluxes such as soda ash, litharge and silica. Add the reducing or oxidizing agent. These must be calculated to suit the nature of the ore for assaying. 4. Mix the sample and reagents thoroughly in the clay crucible and cover the charge with a mixture of borax and soda ash at 2:1 ratio. 5. Charge the crucible in the furnace, pre-heated at 1,000°C. When the charge is completely melted, remove the crucible from the furnace and pour the contents into an iron mould and cool. 6. Break the core of the lead from the slag by hammering and form it into a cube. Place two inquartz into the lead button, also by hammering to press the inquartz into the cube. 7. Put the button into the cupel previously heated inside the furnace. The lead is melted and subsequently oxidized and absorbed by the cupel. An alloy of gold and silver which is called dore remains in the cupel. 8. The dore is cooled, flattened and weighed. 9. The weighed dore is treated with hot nitric acid to dissolve the silver, first with 1:4 then 1:1 HNO 3 to water. It is then washed with distilled water.
H. Guide in Calculating Fluxes, Reducing and Oxidizing Agents 1. Determine the nature of the sample and classify them as siliceous, low sulfide, high sulfide, oxide or basic ore. Each type of ore will have a different combination of fluxes. 2. After the nature of the ore is known, use the following method in calculating the respective reagents.
a) Siliceous Ore 1. Weight of soda ash – weight of ore 2. Calculate for the bisilicate silica equivalent of the soda ash. If there are other basic compounds in the charge, calculate for their bisilicate silica equivalent. 3. Deduct the total silica in step 2 from the silica content of the ore. 4. Add litharge equivalent to the remaining silica. 5. Add litharge for the lead button (the equivalent of 25 g Pb). 6. Add reducing agent
b) Low Sulfide Ore Low sulfide ores are treated as siliceous ores and the slag is aimed to be bisilicate. However, the reducing effect of the ore should be considered.
c) Sulfide Ore 1. Wt. of Na 2 CO 3 = Wt. of ore 2. Wt. od PbO = 2 times the Wt. of ore 3. Calculate bases in the ore 4. Calculate the monosilicate silica equivalent of the basis in steps 1,2, &3. 5. Add silica as flux. 6. Add PbO for button. 7. Find the reducing effect of the ore. Subtract the desired button weight form the reducing effect and divide the result by the oxidizing power of niter. This gives the amount of niter. 8. Add soda ash for the sulfate layer equivalent to ¼ of the niter. 9. Add borax as cover.
d) Basic Ores with Alumina with Bisilicate Slag 1. Add Na 2 CO 3 equal to the weight of the ore. 2. Add litharge for the slag equal to the weight of the ore if low in Al 2 O 3 . If the ore is high in Al 2 O 3 , double the quantity of litharge. 3. Calculate the bases in the ore other than alumina. 4. Calculate the bisilicate silica equivalent of the bases in steps 1,2&3. Deduct the silica in the ore and replace 1/3 of the remaining silica with borax glass. 5. Add more litharge for the button. 6. Add reducer for the button after calculating the oxidizing effects of the bases in the ore. 7. If the ore is high in alumina, estimate the alumina content and provide an equal weight of lime.
I. Calculation of charges for Copper Concentrate 1. Estimate the approximate percent Cu and calculate the weight of the sample such that the Cu content of the charge is not over 7.5 grams. Add Na2CO3 equal to the weight of the ore. 2. Add litharge for the slag equal to 30 times the weight of the copper. 3. Calculate the bases in the ore. 4. Calculate the subsilicate silica equivalent of the bases in steps 1,2 &3. Deduct the silica in the ore. 5. Add more litharge for the button. 6. Calculate the niter by considering the reducing effect of the ore.

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Fire assaying

  • 2. A. Definition and Scope Assaying is the process of determining the proportion of metals in ores and metallurgical products. There has been a tendency to restrict the term to fire methods for the determination of metals so that wet chemical analytical procedures and spectrographic methods of analysis are usually termed “analysis” instead of “assaying”.
  • 3. Fire Assaying is a branch of quantitative chemical analysis where metals are determined in ores and metallurgical products with the aid of heat and dry reagents.
  • 4. Fire assaying is carried out today as much as they were then. This ancient method is still taught in university courses for metallurgist because it offers a convenient way of studying the reaction of igneous chemistry. It is still used in the industries, mining and refineries, because modern science has been unable to develop better methods of determining precious-metal content of ores. This is because, large samples can be economically and accurately assayed by fire method but spectrographic method of analysis are not adopted to operating on large sample portions, while wet chemical method, involving digestion of large samples would be very expensive.
  • 5. The fire assay method is generally applied to gold, silver and some metals in the platinum group. The fire assay of gold and silver depends mainly upon: a. High solubility of these metals in molten metallic lead and their almost complete insolubility in slag. b. The difference in specific gravity between the two liquids, lead and slag, which permits the complete separation of precious metal-bearing lead from the slag. c. Complete removal of lead (Pb) from the previous metals by controlled oxidizing fusion involving differential filtration, in a porous vessel known as cupel. d. The solubility of silver and complete insolubility of gold in dilute nitric acid.
  • 6. B. Objectives of Assaying 1. Valuation of mining property. 2. Basis of buying and selling ores and metallurgical products. 3. Guide to prospecting and development of ore bodies. 4. Delimitation of boundaries of marginal ores.
  • 7. 5. Check against dilution in mining operation. 6. Control of average grade of ore mined and milled. 7. Investigation and control of metallurgical process. 8. Accounting of all metals in process.
  • 8. C. Degree of accuracy required in assaying depends upon which of the above purposes is involved. Highest degree of accuracy on individual sample is necessary in buying and selling ores and metallurgical products, so average of 2 to 3 determinations is a must. If parties do not agree a duplicate pulp is submitted to umpire who reports average of four or more determinations. Samples for mine valuation will need rigid precautions to avoid contamination or accidental salting.
  • 9. Mill tailings and smelter slags require special care since small error will seriously affect the metallurgical balance. Other purposes of assaying as outlined above do not generally require a high degree of precision, single determination with ordinary precaution against errors are usually adequate.
  • 10. D. Unit in Fire Assaying In the USA, Canada and South Africa, the assay of precious metals is expressed as troy ounces per short ton (2000 avoirdupois pound) of ore. A system of assay ton weighs is used in weighing the assay portion of ore, which is taken for assay process. The assay-ton contains the same number of milligrams (29,166), as there are troy ounces in a short ton. Hence, the number of milligrams of precious metal found in an assay-ton of ore indicates the assay in troy ounces per short ton.
  • 11. In the Philippines and other countries including the countries mentioned above who used or shifted to metric system. The proportion of precious metals is reported in grams per metric ton of ore. The metric ton contains 1,000,000 grams; consequently one (1) milligram of gold from a 10-grams assay sample or ore indicates 100 grams per metric ton of ore.
  • 12. E. Requirements in Fire Assaying
  • 13. 1. Apparatus 1. Muffle Furnace - oil fired or electric furnace 2. Balance and Weights - should be sensitive to 0.005 mg at least. It need not have a capacity of more than 1,000 g but should be accurate with that load. 3. Cupels - a flat, shallow crucible of bone ash, used in cupellation. 4. Fusion Crucible - 20 g capacity 5. Iron Mould 6. Annealing Crucible – 10 g Coors porcelain crucible. 7. Hot plate
  • 14. 2. Reagents A flux is a substance which when heated in contact with some difficulty fusible compounds either combines in it or takes it into solution, in each case producing a compound or mixture which is easily fusible at ordinary furnace temperatures. The principle fluxes and other reagents used in fire assaying are the following:
  • 15. 1)Borax and Borax Glass – these are active and readily fusible acid fluxes. These lower the temperature of slag formation and are considered excellent solvent for metallic oxides. These are used as cover to prevent loss of ore which results from the escape of gas at a temperature below that incipient fusion. 2)Silica – acid reagent which combines with metal oxides to form the slag, protects crucible from corrosion. 3)Litharge – basic reagent and aids in the fusion of acid substance. When reduced, it supplies the lead for the button.
  • 16. 4)Soda Ash – basic flux and when molten is very fluid and holds in suspension finely ground infusible materials. To some extent, it reacts with the metallic sulfides to form alkaline sulfide and sulfates. 5)Flour – powerful reducing agent and reduces litharge to lead for the collection of gold and silver. 6)Niter – this is a powerful oxidizing agent. It oxidizes sulfides, arsenides, antimonides. It is used to control the size of the button when the reducing agent effect of the charge is high.
  • 17. F. Process Terminology Involved 1. Sampling – grinding sample too fine a mesh should be avoided, 80-120 mesh is probably the best range. 2. Fusion – melting together of the fluxes and the sample at 1,000°C. Time ranges from 40-50 minutes. A long-continued fusion at low temperature means a small lead button (ideal weight is 23-30 g), and an imperfect collection of gold and silver. Pouring melt in molds separates lead buttons which are hammered in rough cubes. 3. Cupellation – the separation of gold and silver in a cupel, wherein the impurities are volatilized or absorbed by the cupel, and a button of noble metal known as dore (an alloy of gold and silver left after cupellation) is left. Pre-heat the cupel in the furnace for at least 20 minutes. Starting temperature is ideal at 900°C.
  • 18. 4. Parting – the separation of gold from silver by dissolution with dilute nitric acid. 5. Annealing – tempering by heating, then cooling, to render the gold less brittle. 6. Weighing – values may sometimes be nil (not visible) or trace (visible but negligible in weight). 7. Inquartation – addition of inquartz with known Ag content.
  • 19. G. Procedure 1. After drying the sample, stage-crush to minus 1.82 mm and reduce by a series of crushing, mixing and cutting until the desired amount of approximately 300 grams is obtained for pulverizing to minus 100 mesh. 2. Mix the sample thoroughly by rolling in a rubber cloth and scoop sample at random for weighing. Normally 10, 15, 20 or 30 grams is used depending on the grade of the precious metal. 3. Add the necessary fluxes such as soda ash, litharge and silica. Add the reducing or oxidizing agent. These must be calculated to suit the nature of the ore for assaying. 4. Mix the sample and reagents thoroughly in the clay crucible and cover the charge with a mixture of borax and soda ash at 2:1 ratio. 5. Charge the crucible in the furnace, pre-heated at 1,000°C. When the charge is completely melted, remove the crucible from the furnace and pour the contents into an iron mould and cool. 6. Break the core of the lead from the slag by hammering and form it into a cube. Place two inquartz into the lead button, also by hammering to press the inquartz into the cube. 7. Put the button into the cupel previously heated inside the furnace. The lead is melted and subsequently oxidized and absorbed by the cupel. An alloy of gold and silver which is called dore remains in the cupel. 8. The dore is cooled, flattened and weighed. 9. The weighed dore is treated with hot nitric acid to dissolve the silver, first with 1:4 then 1:1 HNO 3 to water. It is then washed with distilled water.
  • 20. H. Guide in Calculating Fluxes, Reducing and Oxidizing Agents 1. Determine the nature of the sample and classify them as siliceous, low sulfide, high sulfide, oxide or basic ore. Each type of ore will have a different combination of fluxes. 2. After the nature of the ore is known, use the following method in calculating the respective reagents.
  • 21. a) Siliceous Ore 1. Weight of soda ash – weight of ore 2. Calculate for the bisilicate silica equivalent of the soda ash. If there are other basic compounds in the charge, calculate for their bisilicate silica equivalent. 3. Deduct the total silica in step 2 from the silica content of the ore. 4. Add litharge equivalent to the remaining silica. 5. Add litharge for the lead button (the equivalent of 25 g Pb). 6. Add reducing agent
  • 22. b) Low Sulfide Ore Low sulfide ores are treated as siliceous ores and the slag is aimed to be bisilicate. However, the reducing effect of the ore should be considered.
  • 23. c) Sulfide Ore 1. Wt. of Na 2 CO 3 = Wt. of ore 2. Wt. od PbO = 2 times the Wt. of ore 3. Calculate bases in the ore 4. Calculate the monosilicate silica equivalent of the basis in steps 1,2, &3. 5. Add silica as flux. 6. Add PbO for button. 7. Find the reducing effect of the ore. Subtract the desired button weight form the reducing effect and divide the result by the oxidizing power of niter. This gives the amount of niter. 8. Add soda ash for the sulfate layer equivalent to ¼ of the niter. 9. Add borax as cover.
  • 24. d) Basic Ores with Alumina with Bisilicate Slag 1. Add Na 2 CO 3 equal to the weight of the ore. 2. Add litharge for the slag equal to the weight of the ore if low in Al 2 O 3 . If the ore is high in Al 2 O 3 , double the quantity of litharge. 3. Calculate the bases in the ore other than alumina. 4. Calculate the bisilicate silica equivalent of the bases in steps 1,2&3. Deduct the silica in the ore and replace 1/3 of the remaining silica with borax glass. 5. Add more litharge for the button. 6. Add reducer for the button after calculating the oxidizing effects of the bases in the ore. 7. If the ore is high in alumina, estimate the alumina content and provide an equal weight of lime.
  • 25. I. Calculation of charges for Copper Concentrate 1. Estimate the approximate percent Cu and calculate the weight of the sample such that the Cu content of the charge is not over 7.5 grams. Add Na2CO3 equal to the weight of the ore. 2. Add litharge for the slag equal to 30 times the weight of the copper. 3. Calculate the bases in the ore. 4. Calculate the subsilicate silica equivalent of the bases in steps 1,2 &3. Deduct the silica in the ore. 5. Add more litharge for the button. 6. Calculate the niter by considering the reducing effect of the ore.