Search Results : merrill-crowe process

Gold Mining Process Development

 

THE BASIC PROCESSES OF GOLD RECOVERY

INTRODUCTION

Man has held a fascination with recovering and acquiring gold almost since
the beginning of time. This paper will attempt to put the multitude of recovery
processes into a current day perspective.

An underlying theme of this paper is that the mineralogy of the ore will
determine the best recovery process and that metallurgical testing is almost
always required to optimize a recovery flowsheet.

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 Posted by at 2:46 pm

Merrill Crowe Systems

 

The Merril-Crowe Gold recovery Process

The Merrill-Crowe gold recovery process removes precious metals from a cyanide solution by zinc precipitation.

The pregnant solution is first clarified through filters such as horizontal leaf type clarifiers. By using a precoat system (with diatomaceous earth) an extremely clear solution can be produced. The specific design criteria for these types of filters vary with the turbidity of the leach solutions. To avoid major upsets in the circuit, two filters should be online while another is being cleaned, precoated, and readied to go online as the next filter goes out of service. The solids removed by these filters are of no value and are backflushed to tails.

The vacuum system removes oxygen from the solution in a packed tower. Solution is percolated through a packing bed while under a vacuum. Flashing water vapor strips oxygen from the solution. Special attention must be paid to eliminating any air leaking into the tower, as this can decrease the efficiency of the vacuum system. Solution exits from the bottom of the tower and results in a very low net suction head on the precipitate feed pumps. A careful selection of these pumps will avoid cavitation and the tendency to pull air back into the solution. It should also be noted that these pumps will require liquid seal in the packing area so that air does not leak into back solution. Zinc feed addition utilizes a zinc feeder with an auger and moving side walls to avoid bridging of the material. Using a cone bottom tank with a steady head tank for zinc mixing solution (usually a cyanide solution) will assure that no air will leak into the system. With a rich pregnant solution, the zinc will be better utilized, and conversely, with a weak pregnant solution it will be less utilized.

Using lead nitrate in the zinc system can activate the zinc. It must be used in low dosages to prevent blinding off the surface of the zinc and preventing precipitation of precious metals. An excessive use of lead nitrate can form a lead hydroxide gel and blind the filters.

Zinc must be added at a constant rate. A variable speed feeder is recommended for this application. The zinc must be kept dry to keep it free flowing. The zinc solution is added to the line between the deaeration tower and the precipitate feed pumps.

Final filtration of the precious metals is accomplished with the precipitate filter feed pumps and filter presses. The feed pumps must have submerged liquid seals over the packing area or flushed double mechanical seals, and have a low NPSH requirement. Most filters are either the plate and frame type or the recessed plate type. Filter cake is collected in the chambers between the plates and can be air blown to remove a substantial amount of water.

 

 Posted by at 10:40 pm

CIP History

 

CARBON-IN-PULP PIONEERING AT THE CARLTON MILL


 

HOW CIP PROCESSING BLOSSOMED AS A ROUTINE AT GOLDEN CYCLE IN THE 1950s

John L. Fast, President, Denver Mineral Engineers, Inc.

The affinity of carbon for gold has long been known, and has often caused
premature precipitation problems or losses of precious metals in early cyanide
plants treating graphitic or carbonaceous ores. Many writers have dated the
carbon-in-pulp “renaissance” with the August, 1973, commissioning of the
CIP circuit at Homestake Mining Co.’s plant in Lead, South Dakota (then a
2,200 st/d mill). But the fact is, that the process was used commercially
at least 22 years earlier, demonstrating once again that much that is new
in contemporary mineral processing has been tried before and forgotten, because
the development was either ahead of its time or not useful in the prevailing
economic climate.

Golden Cycle Gold Corp.’s Carlton mill at Cripple Creek, Colo., was the first
major operation to employ carbon-in-pulp recovery for the winning of gold
from ores. Started in 1951 as a 1,000 st/d custom tolling plant that treated
telluride ores of the Cripple Creek/Victor district1.2, the Carlton mill
ran until 1961. The flowsheet employed fluid-bed roasting of the concentrates
and flotation, followed by cyanidation of the calcine and zinc precipitation
of gold. Flotation tailing and concentrate cyanidation tailing were treated
in a carbon-in-pulp cyanidation circuit that was remarkably similar to those
in operation today.

The CIP cyanidation circuit consisted of three 40-ft-dia leach tanks followed
by three 40-ft-dia CIP adsorption vessels. All were equipped with low-speed
agitators and arranged in stepped, one-ft height sequences to provide for
gravitational flow of slurry.

Gold was initially recovered from the carbon by an ammonia-stripping process
developed by the Merrill Co. of Merrill-Crowe fame3. Carbon loaded with gold
was placed in a stripping vessel that was then filled with an aqueous ammonia
solution. The column was then pressurized with ammonia gas, and heat was
applied to the column base.Ammonia vapors exiting the top were condensed
and recycled to the column. Distillation refluxing at 150 lb/in.2 of pressure
continued until the column bottom liquor consisted of a gold-laden water
solution. Gold was recovered from this solution by precipitation with zinc
dust. The column was automatically controlled, and the Golden Cycle staff
had been assured that the unit would operate “similar to a refrigerator.”

Unfortunately, the stripping unit soon became inoperable due to sludge formation
in the “still.” The process was sound metallurgically, but mechanically the
system was too complicated to operate in a mill environment4. The stripping
operation was then converted to the Zadra desorption and electrowinning process
developed by the US BM5.

The Zadra process proved to be easily controllable by the average operator.
Carbon batches of 1,500 to 2,000 lb were contacted with 1% (weight) sodium
hydroxide and 0.1% (weight) sodium cyanide solution at about 193’F for 24
to 36 hr. Solution exiting desorption passed through a Zadra electrowinning
cell and then recycled to stripping. Caustic and cyanide were added to the
recycled solution whenever carbon batches were changed, and the entire batch
of strip solution was discarded every two weeks when steel wool in the
electrowinning cell was changed. Gold-loaded steel wool was smelted in Rockwell
furnaces6.

CARBON REGENERATION

Another major problem developed shortly after the mill start-up. The carbon
rapidly lost much of its activity as it was cycled through the process.
Researchers at both the Merrill Co. and the US Bureau of Mines concluded
that carbon fouling from carry-over of flotation reagents was causing the
deactivation 7,8,9,10. Both groups suggested thermal reactivation of the
carbon, and the Merrill Co. was selected to design and supply a carbon
regenerator.

The kiln installed in 1952 was a 20-in.-dia x 12.6-ft-long, indirectly heated,
rotary calciner. Originally, the kiln was electrically heated and could
regenerate about 500 lb/d of carbon. The electric heaters were soon replaced
with gas burners and the capacity increased to 1,500 lb/d of carbon when
held 10 to 15 min. at temperatures of 1,100 to 1,200’F. This hastily designed
kiln was nearly identical to the regeneration units of today. Procedures
for acid washing of the carbon were also developed by the US Bureau of Mines
during this period”.

The carbon used at the Carlton mill was a 10 x 20 mesh-sized product made
from peach and apricot pits. It was recognized that coconut-shell carbon
would have been more attrition-resistant, but fruit-pit carbon was available
for about half the price of coconut-shell carbon and proved highly satisfactory
for the service. Carbon losses in the circuit averaged about 0.09 lb/st of
ore processed.

CIP TANK SCREENS

Initially, 8-ft-dia x 12-ft-long, rotary trommel screens were used in the
CIP tanks for carbon retention. The ore-carbon slurry flowed out of one tank
and entered the open end of the revolving screen in the next tank. Ore pulp
passed through the screen, which detained the carbon on the screen surface.
As the trommel rotated, carbon was elevated. The water sprays directed such
carbon to a launder for return to the originating tank during normal operation
or diverted it to another launder for countercurrent carbon movement to the
next upstream tank.

The design of the screens had been developed and tested by the Merrill Co.
in a 50 st/d pilot plant that established screen capacity as a function of
pulp density, carbon concentration, and screen mesh.

Operation of the trommel screens was never considered entirely successful.
Mechanical support of the screens was unsatisfactory, partially because a
cantilevered structure was needed to keep one end of the screen open for
slurry feed. Also, at higher carbon concentrations, the carbon would build
up in layers and fall back on the screen, rather than be washed to a launder.
Still another problem with the screens was dilution of the pulp from the
sprays and launder transport water. Typically, slurry would enter CIP at
43% solids and exit at 35% solids (by weight).

To correct such problems, external air lifts were installed to elevate the
carbon-ore slurry to rectangular 3 x 4-ft vibrating screens mounted above
the tanks. Built in company shops, these screens were equipped with two off
balance flywheels to provide a vibratory action. Carbon exiting the screen
surface would normally drop back into the originating tank or be diverted
to the upstream tank if a carbon advance was desired. Ore slurry passing
through the screens flowed by gravity to the next tank.

The installation of the vibrating screens 1-1/2 yr. after the mill start-up
solved the last major problem in the CIP circuit. The Carlton mill continued
to run satisfactorily until it was closed in 1961, a casualty of $35 gold.
However, it was reopened in 1981 as a concentrator based on flotation only.
Recently, it was again converted to a carbon-in-pulp flow-sheet.

In retrospect, the original Carlton CIP was a forerunner of things to come
and perhaps ahead of its time.

John L. Fast is a registered professional engineer and has been involved
in the design of over 20 gold and silver recovery projects. Denver Mineral
Engineers, Inc. specializes in the design and manufacture of precious metals
recovery equipment and systems. The author extends acknowledgements and thanks
to Alan Turner and the library staff of Stearns Roger Division, United Engineers
and Constructors Inc., for allowing access to the company files that provided
documentation for this article.

REFERENCES

1) “Flowsheet-The Carlton Mill,” Mill Tour sponsored by School District
No. 1, Summer, 1959

2) “New Carlton Mill Nears Completion,” Engineering and Mining Journal,
September 1950.

3) Keil H. R., “Notes on Trip to Merrill Co.,” Oct. 18, 1950.

4) Keil H. R., “Letter to G. Norris, West African Gold Corp., Ltd.,”
Sept. 20,1952.

5) Zadra, J. B., Engle, A.L, and Heinen, H. S., “Process for Recovering
Gold and Silver from Activated

Carbon by Leaching and Electrolysis,” US Bureau of Mines, RI 4843,
1952.

6) Keil, H. R., “Carbon Cyanidation at the Carlton Mill,” May
1957.

7) Byler, R. E., “Letter to Max Bowen, Golden Cycle Corp.,” March
21, 1952.

8) Zadra, J. B., “Golden Cycle-Case Study of Ore, Flotation, Cyanidation,
and the Use of Activated Carbon,” Progress Report, US Bureau
of Mines, Jan. 9, 1952.

9) Zadra, J. B., “Golden Cycle of Ore and Carbon,” Progress Report
No. 2, US Bureau of Mines, Jan. 30, 1952.

10) Zadra, J. B., “Golden Cycle of Ore and Carbon,” Progress Report
No. 3, US Bureau of Mines, March 12,1952.

11) Zadra, J. B., “Golden Cycle Carbon Investigation,” Progress Report
No. 4, US Bureau of Mines, Aug. 1, 1952.

JUNE 1988

 


Fast & Associates, LLC

Denver Mineral Engineers, Inc.
10641 Flatiron Rd.
Littleton, CO 80124 USA
sales@denvermineral.com

 Posted by at 3:16 pm

Consulting Services

 

JOHN L. FAST

Consulting Process Engineer

Over 35 years experience in mining, chemical processing, equipment manufacturing, engineering and steel fabrication; as business owner, engineer and consultant.

2004 to present
General Manager   Fast & Associates, LLC dba Denver Mineral Engineers
Consulting services in the areas of gold and silver mining, mercury processing, and product support for the Denver Mineral Engineers line of process equipment.  Areas of emphasis include mercury retorting, heap leaching, cyanide leaching, carbon adsorption and stripping, electrowinning, zinc precipitation (Merrill-Crowe), and carbon regeneration.
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 Posted by at 2:38 pm

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Melting FurnaceDENVER MINERAL ENGINEERS offers consulting services, designs and a range of mining process equipment for cyanide gold recovery, water treatment and mineral processing. Our equipment has recovered over 50 million ounces of gold at mines around the world.  With involvement in over 250 gold and silver mining projects over the past 30 years we can help to advance your mining activities in many ways.

Products include: carbon column systems; electrowinning cells; melting furnaces; carbon stripping systems; ADR and Merrill-Crowe plants; carbon regeneration systems and mercury retorts. Other mineral processing items made by DME include mixer-settler units, acid wash units, sieve bend screens, CIP tank screens, filter presses, deaerators, zinc cones, solution samplers, dart valves, vibrating screens, solids feeders, sand filters, and more. Modular heap leach recovery plants and water treatment systems with capacities up to 3500 GPM offer very economical alternatives to conventional field constructed plants.  Currently, most of the custom fabricated equipment shown on this website is only offered on an EPCM or consulting/royalty type basis and not by lump sum pricing.  However, the entire DME design file may be utilized in conjunction with our consulting services.

The information contained in this website is for general information purposes only. The information is provided by Denver Mineral Engineers and while we endeavor to keep the information up to date and correct, we make no representations or warranties of any kind, express or implied, about the completeness, accuracy, reliability, suitability or availability with respect to the website or the information, products, services, or related graphics contained on the website for any purpose. Any reliance you place on such information is therefore strictly at your own risk. In no event will we be liable for any loss or damage including without limitation, indirect or consequential loss or damage, or any loss or damage whatsoever arising from loss of data or profits arising out of, or in connection with, the use of this website.

Fast & Associates, LLC

Denver Mineral Engineers, Inc.
10641 Flatiron Rd.
Littleton, CO 80124 USA
sales@denvermineral.com

 Posted by at 5:01 pm