A Very Busy Commissioning Time | Mining Equipment Manufacturing and Installation with APT

APT is renowned for the fast build lead times of it’s modular plants, but you may not be aware of the ultra-fast installation and commissioning times that can be achieved with a properly engineered product. About eight years ago a situation arose that tested APT’s abilities to the limit, a ‘perfect commissioning storm’ – four plants at once. These were all RG based gravity plants, one in Sierra Leone for gold, one in Colombia for gold and platinum, one for gold in the eastern DRC on the Ugandan border, and one for chromite in Limpopo, South Africa. All were RG200 based 20tph plants, except the chromite one which was an RG800 at 80tph.  

The plan was made upon almost military lines: Neil would be the commander on the Sierra Leone one with Jason in assistance. The second that was done Jason would be the commander on the DRC one, I can’t recall his assistant. Simultaneously Neil and I would fly half way across the world to Columbia, and as soon as that was done, Neil and I would be joined by Derek and Martin to do the large Limpopo chromite project. 

Zero hour arrived and the Sierra Leone team dispatched, only to find the client hadn’t even started their concrete pad they said was finished. So they roped in a bull dozer and levelled a piece of ground and installed the plant on that as there was no possibility of stopping the clock now. Duly completed and some gold produced for the client, Jason and team headed off in a helicopter from Uganda across Lake Victoria and immediately got stuck into installing the second plant that had taken months to truck in over extremely rough terrain on 4x4 vehicles. Half way through a message was received that rebels were on their way, so the team stepped it up, got the plant built, processed some material and smelted a gold button in 72 hours, a record that still stands for us. In the meanwhile Neil and I arrived in the Colombian lowlands and soon learnt that this was in the FARC area, so we were escorted to and from site daily by military convoy. We stood ready to commence assembly, but no plant. It transpired that there had been a landslide in the mountains and the trucks were held up. Four days later they arrived and all went well, despite using a teetering excavator as a crane to lift loads well beyond its capacity. They were supposed to use a crane, but just shrugged shoulders. Job done, we headed back to South Africa to the relative comfort and safety of a game lodge as our base to install the RG800, which went off without a hitch.  

I swear that when we got back to the office everyone on these teams looked taller and definitely got a touch of sun, but little was said, as operations are never spread about. 

Small and Medium Scale Hard Rock Processing Plants for Rapid Gold Production

We at APT are proud to bring you our RD50 and RD100 Hard Rock Processing Plants, offering highly economical solutions for rapid gold production on a small to medium scale. Leading on from our small scale RDGK, these two robust and compact solutions are rated for up to 5tph and 10tph respectively, and are perfectly suited to the liberation of minerals at a relatively coarse size.

GK-X Tailings Plant

Q: What is it?         

A: The GK-X Tailings Plant is a simple plant to allow feeding up to 10tph into a GK-X concentrator. Material is dumped into the tray feeder and water monitored into the GK-X concentrator.  

Q: Why was it introduced/what is its purpose?         

A: Its purpose is to capture free gold and residual mercury from tailings. This simple tray feeder plant was introduced because it is not necessary to have a scrubbing drum for these loose tailings.

Q: Benefits?                         

A: Capital cost is much lower than a formal RG scrubbing plant, which in this case is unnecessary. The plant is small and compact and therefore easy to set up initially and then move thereafter.

RD50 Hard Rock Plant

Q: What is it?                       

A: The RD50 is an RD impact crusher coupled with a simple tray manual feeder for the rock at -70mm size. Capacity is up to 5tph.

Q: Why was it introduced/what is its purpose?         

A: This plant was designed to crush rock to liberate the gold via impact crusher and then capture this in APT’s GoldKacha concentrators. The system uses a very simple feed tray to manually feed the RD50 crusher with the slurry feeding directly to 3 x GoldKacha concentrators.

Q: Benefits? 

A: The system is extremely simple and cost effective but has the same metallurgical performance as more complex and costly plants.

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RD50 Small Scale Hard Rock Processing Plant

4-5tph solution by APT

RD100 Hard Rock Plant

Q: What is it?                       

A: The RD100 is made up of 2 x RD50 impactor mills in parallel, feeding their slurry to APT’s GK-X high G centrifugal concentrator. Capacity is up to 10tph.

Why was it introduced/what is its purpose?

A: The purpose is to crush rock to liberate the gold via impact crusher and then capture the gold in one of APT’s GK-X centrifugal concentrators.

Q: Benefits?                         

A: The system is extremely simple and cost effective but has the same metallurgical performance as more complex and costly plants.

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RD100 Medium Scale Hard Rock Processing Plant

8-10tph solution by APT

For further information, please email us on info@aptprocessing.com or contact us here.

Graphite Processing, the APT Way | Graphite Processing FAQ's

Q: What is special about APT’s graphite processing methodology?

A: The coarser that one can obtain graphite flake at grade, the more valuable the product. APT’s system has a number of features that enable this to happen.

Q: What is the recovery mechanism in APT’s system?

A: As in all graphite plants, we also use flotation, but the flotation happens in APT’s own proprietary TriFloat flotation cells.

Q: What is special about the APT TriFloat?

A: The TriFloat was developed specifically for high yield minerals like graphite, by which we mean that the feed can sometimes be over 30% in grade, so there is a lot of concentrate to collect. The TriFloat has a high ratio of lip length to cell volume, so it is easier for the high volume of froth to exit the cell. Secondly, the TriFloat rotor-stator mechanism is positioned towards the back of the triangular cell which creates a pinch point that pushes the floated froth forwards towards the lip. Thirdly, once the froth gets to the lip area, there is a quieter zone so the froth isn’t re-stirred into the slurry again. Fourthly, the TriFloat geometry enables flotation to happen at a coarser size, so even 2mm is acceptable. 

Q: How is the feed prepared for the TriFloat?

A: The APT system uses its own RD series wet hammer mills fitted with a 2mm or 3mm internal screen. The graphite is very well liberated by this system without over-breaking flake as happens in a rod mill or ball mill. There is also a jaw crusher up front to break to feed ore down to minus 40mm.

Q: Is it necessary to have a rod mill in the circuit and use multiple grind-float stages as happens in conventional graphite circuits?

A: The primary recovery is very high, leaving very little behind. Also the primary concentrate is cleaned again so final concentrate grade is also very high. Adding a rod mill on the primary flotation tails to scavenge the little that remains is hardly worth the extra capital cost and complexity, but APT can add this if the client desires. It is still less complex than a conventional circuit.

Q: What scale can the APT Graphite system be applied at?

A: Modules are available from 1tph up to 20tph of feed ore.

Q: What are the implications for plant installation?

A: The plant is very simple – crushing, impacting, Trifloat, concentrate collection and dewatering in dual troughs (thickening and filtration is way to expensive at this scale.) The plant is therefore compact and small and a fraction of the price of a conventional plant. The site preparation requires a simple flat concrete screed with brick or concrete built settlement bunkers for the concentrates. Concentrate cake can be sun dried or dried in a simple fired kiln. Installation of a system on site is usually very quick.

Q: How do we test the system on our own ore?

A: APT’s associate laboratory Peacocke & Simpson is equipped with impactors and TriFloats at bench scale and 60kg pilot scale. A 200kg sample is required. The procedure involves first floating and cleaning at bench scale as a base case, and then at 60kg with a cleaner stage and locked cycle if required. Concentrates are screened and assayed for TGC.

Carbon Elution System | APT ELU-X FAQ'S

Q: What is an APT Elu-X? 

A: APT’s Elu-X is a carbon elution system that compliments other APT processes, such as the APT TriTank Carbon In Leach or CIP systems. These systems are continuous in that ore is fed into the CIL continuously, but the loaded carbon is harvested once a day. The loaded carbon is then treated in batches and then discharged before being fed back into the CIL or CIP. 

Q: What is an Elu-X used for? 

A: The Elu-X is used to remove the gold from activated carbon which has been loaded with the gold in a cyanidation system like CIP or CIL. So first the gold is dissolved in the cyanide slurry, then it is adsorbed onto the activated carbon and the final stage is getting the gold off the activated carbon. That is called elution. 

Q: How does elution work? 

A: The carbon with the gold adsorbed on it is placed into a vessel called an elution column. A solution of hot sodium hydroxide and cyanide in water is then pumped through the carbon in the column and as it rises through the column, it dissolves  or de-sorbes some of the gold. The solution, now with the gold dissolved in it, then passes through an electrowinning cell. An electric current is applied to the cell between the anode and the cathode which causes the gold to plate out onto the cathode. The solution, now with the gold removed, is reheated between being pumped through the column to dissolve off more gold. The whole process is continued for about two days by which time the gold has been removed from the carbon and deposited onto the cathode. The final step is to remove the cathode, which is normally made from steel wool, and dissolve it in acid to give gold sludge. This is then dried and smelted with borax to get the gold bullion. The carbon, now stripped of the gold, is returned to the CIL system to load more gold from the slurry. 

The spent cyanide and sodium hydroxide solution will still have a little gold in it and also some value due to the cyanide and alkalinity value. It is therefore fed back into the first sector or tank of the CIL train. 

Q: Can elution be used to recover any other metals like silver and copper? 

A: No, elution as applied in the APT Elu-X is for gold only.  

Q: Are there different types of elution systems? 

A: Yes, the three most common ones are Atmospheric or Open ZadraPressurised or Closed Zadra and AARL. The Pressurised Zadra is the fastest, but being at high temperatures and pressure it is more sophisticated and also more dangerous if there was a leak. The pressurized Zadra system typically takes one day to complete a cycle. Open Zadra is what is used in the APT Elu-X and although slower, taking typically two days to complete a cycle, it is less sophisticated, easier to use and less dangerous.  

Q: Does the spent carbon need need any further treatment before being put back into the CIL tanks? 

A: If your ore or your process requires a lot of lime, then it is useful to acid wash the carbon to get this off before putting the carbon back into the leach train. To do this, the carbon is dipped into a solution of about 5% hydrochloric acid and left there until the effervescent reaction stops. Alternatively the carbon can be placed into an acid washing column and the dilute acid then pumped into the column to cover it. The process normally only takes less than an hour. *CAUTION – mixing acid with cyanide produces a lethal gas. The carbon must therefore be thoroughly washed with water to remove all cyanide before it is contacted with acid. The wash water should be placed back into the CIL train. After acid washing the carbon must again be thoroughly washed with water to remove the acid, but this time the acidic wash water needs to be neutralized with sodium hydroxide to pH 8 before being discarded.  

When the carbon activity, or its ability to adsorb gold falls to a low level it needs to be thermally re-activated or regenerated. This happens in a carbon regen kiln that is a separate supply item and process. The carbon to be regenerated must be acid washed first. Because regen kilns are expensive and only need to be used periodically, most smaller operators will outsource this service to a custom regen centre. 

Q: What sort of capacities do Elu-X systems come in? 

A: The smallest is the Elu-X270, it has a capacity of 270kg of carbon and is used for cyanidation systems treating up to 3 tonnes of  ore per hour.  

Then comes the Elu-X540, with a capacity of 540kg of carbon and used for cyanidation systems treating up to 6 tonnes of ore per hour.  

Then Elu-X750 for cyanidation systems treating up to 10 tonnes of ore per hour.  

Finally the Elu-X1500 with a capacity of 1500kg of carbon suitable for cyanidation systems treating up to 20 tonnes of ore per hour.  

Beyond that APT recommends more sophisticated Pressurised Zadra systems which are sourced outhouse. 

Q: Do I need special skills to operate APT’s Elu-X? 

A: The system is fairly simple and the manual can be used to guide you, but because it is a cyanidation system it is potentially dangerous if not operated properly. Also, each batch of carbon contains high gold value and incorrect operation could lose some gold. Therefore only persons with experience in operation elution systems and preferably qualified in cyanidation systems should operate the Elu-X. 

Evaluating an Alluvial Gold Deposit | Mining FAQ'S

Q: Is it possible to absolutely and accurately evaluate an alluvial reserve? 

A: No, it is very difficult to do that because the gold is very unevenly distributed. The best you an do it take bulk samples from several areas to get a reasonable idea. The more samples you take, the more accurate the assessment will be. 

Q: What is the best way to evaluate an alluvial deposit? 

A: The best method is to do an in-field pilot plant exercise treating sample batches of a minimum of 3 tonnes per batch.  

Q: How is this pilot testing best achieved? 

A: It is important that the pilot plant you select mimics the proposed full scale process in the future. So it must include scrubbing to break down the feed and disintegrate any clays as these will hold gold. It must then screen off the large rock and then send the fines to an efficient gold concentrator. Finally the concentrate needs to be collected and efficiently upgraded to a point where the high grade concentrate can either be sent to a laboratory for total assay, or the gold collected on site and weighed. This is why a  large starting sample of at least 3 tonnes is required, not only to be more representative, but to give enough gold to capture and accurately weigh.  

Q: Is all the gold in the fines, or will there also be gold nuggets? 

A: There can be both, particularly if the source of the alluvial was nearby.  

Q: What sort of equipment is involved? 

A: APT recommends the RG30 scrubber fitted with a  3mm trommel screen and the -3mm feeding to a GoldKacha concentrator. The GoldKacha tails then go over a small GoldMasta sluice to make sure no gold escapes. The concentrate from the GoldKacha and the GoldMasta sluice are combined and upgraded by feeding slowly over a GoldKonka upgrade system and finally panning the GoldKonka concentrate to see the gold. The gold can be hand picked, or carefully panned to purity, or better still the final concentrate sent to a lab for Total Fusion assay to give the grams of gold present. The oversize rock is then screened on a 15mm screen by hand and the -15mm is fed to a GoldJigga hand jig to recover any nuggets. The +15mm can be inspected visually for any large pieces of gold, but this is very rare. The plant can be trailer mounted or free standing. Although trailer mounting makes t easier to move from place to place, it is more expensive. APT sells all of the above equipment. 

Q: How do you use all of the information to evaluate the deposit? 

A: Firstly you need to know how much sample was taken, for example 3 tonnes, so that you can work the yield back to the in-situ amount in grams per tonne recovery. Then you need to estimate or measure the amount of rock that is +3mm as this will assist in choosing the type of full-scale plant you need. Thirdly you need to know the amount of gold present in the -3mm. Finally you need to know the gold present as nuggets. You can then calculate the total gold yield as well as the fine gold and the coarse gold yield. 

Q: If we send the gravity concentrates to the laboratory what should we request them to do? 

A: It is critically important that the laboratory does a Total Fusion Assay of the whole sample and not the normal grams per tonne assay. So they will report back to you the actual amount of gold from the fusion in grams. To enable them to do this, the sample you send to them needs to be as small as possible, maximum of 50 grams. You should also request them to do a micro photo of the gold showing the size and shape of the particles against a scale. This is important information in fine tuning the best plant in practice. The Peacocke & Simpson laboratory understands the procedure and has the equipment to do this work.  

Q: Once I have the evaluation information how do I choose the correct plant? 

A: This is a specialized task best left to the experts. For example, if your gold was mostly fine, then  the finest screen on the plant trommel that is practically feasible needs to be chosen. Furthermore, the concentrate cleanup table needs to be chosen to maximise the recovery of the fines or a large proportion of the primary recovery will be lost again. If you also had nuggets, then the plant needs to also incorporate a nugget trap. APT has all the knowhow and all of the necessary equipment 

Starting Gold Mining? | We answer your frequently asked questions to to help you make your mining choices

Q :What kind of gold resources are there?

A: Gold can occur in loose oxide near the surface or as the deposit gets deeper the host rock becomes harder. Sometimes as depth increases and sulphide minerals occur, the gold will be in the silicates as well as the sulphide minerals. The deep level ore is called hard rock, the surface ore is called oxides.

Alluvial deposits are associated with rivers and the gold occurs as nuggets or fine gold. There is no gold in the hard rock in an alluvial deposit.

An elluvial deposit is one that was also deposited by rivers or water a long time ago and it may now be far from any river. Again the gold is free and there is no gold in the rocks.

Tailings are what is left over after miners have treated the ore before. There is little or no free gold left.

Q: What process do I choose for each of the types of resource?

A: For alluvial or elluvial ore you first dig up the material, then put it through a scrubber to break up lumps and liberate all the gold particles. After this, the slurry is passed through a gravity concentrator.

For surface oxides the ore is crushed down to liberate the gold and then the resulting slurry goes through a gravity concentrator. Sometimes if the ore is ‘soft’ it helps to use a scrubber up front to break up and liberate the ‘soft’ part and then you only have to crush the hard component. The slurry from the scrubber and from the crushing go together through a gravity concentrator. *See the later section on ‘High Energy Impacting’ which APT uses for this type of ore. If there is still enough gold left in the gangue (or waste) particles after impacting, then they must be sent to cyanidation. *See ‘Types of Cyanidation’ further down.

Hard Rock needs to be crushed and milled to about 75 microns in a jaw crusher followed by a ball mill. The fine slurry is then sent to an agitated cyanidation system. If there is enough free gold present, say 30% or more, then a gravity circuit can be installed with the ball mill and the gravity tailings go to the cyanidation agitators. If the gold occurs with the sulphides then it may be possible to float out the sulphides after milling using a system like APT’s TriFloat. The flotation concentrate is then either ground further and agitated in cyanide, or simply sold as is into the market. The cyanidation of a flotation circuit cannot happen with carbon as in a CIL, but requires thickening, filtration and Merrill Crowe zinc precipitation. This is a specialized process that cannot be performed at small scale.

Q: What kinds of cyanidation plants are there?

A: The simplest form is vat leaching where you charge the dry material into the first set of tanks and then fill them with cyanide solution. The solution then percolates through the charge and dissolves the gold. Finally the solution with the gold in it passes through carbon or zinc to deposit the gold out of the solution. Usually only coarser material like sand is suitable for percolation leaching or the solution wont pass through easily. Vat leaching takes longer (4 to 8 days) and is normally not as efficient as stirred tank cyanidation. The simplest stirred tank agitated cyanidation system is CIL (Carbon In Leach). This is used when the gold dissolves rapidly so that dissolution is complete within 12 hours. In this case the carbon is added to the first tank and gold dissolution and gold adsorption onto the carbon happen together. Where the dissolution is slower requiring more than 18 hours, the usual system is CIP (Carbon In Pulp). Here the dissolution is carried out first without carbon and when the gold is dissolved, carbon is added in a second set of tanks called the adsorption train.

In this article we are referring to CIL or CIP, not vat leaching.

Q: Will a gravity system recover all of the gold?

A: No, it will only recover part of it. There will always be something left in the gravity tailings. That is why it is common to start with a gravity system and then add a cyanidation module on later when it is required and you have built up some capital.

Q: Which is cheaper: gravity or cyanidation?

A: Gravity is much cheaper in terms of both the initial capital outlay for the plant and then the operating cost. Cyanidation equipment is more expensive to buy and more expensive to operate as the power consumption is higher and you also need to buy cyanide and lime.

Q: Do you need to grind to the same size for both gravity and cyanidation recovery?

A: Cyanidation recovery requires the ore to be finely ground to about 75 microns and to achieve this you need a ball mill and classifier, as well as the pre-crushing steps to get the ore to about 20mm in size. Gravity recovery will also benefit from fine grinding in a ball mill, but you can get almost the same gravity recovery from using a High Energy Impactor. This is because the ore is shattered by the impact bars and breaks on the grain boundaries where the gold usually is. So you get gold liberation without grinding the rest of the grains. This is called ‘Early Liberation’.

Q: What size do I need to grind to with a High Energy Impactor to get early liberation?

A: The usual size is 2mm, as dictated by the internal screen fitted to the High Energy Impactor.

Q: How does a High Energy Impactor differ from a normal hammer mill?

A: The High Energy Impactor has two solid bars that are much bigger than in a hammer mill which has many little hammers like fingers. The bars are rotated much faster than a hammer mill and impart far higher breakage energy, without which you won’t get early liberation. The machine needs to be far stronger and built with proper bearings to withstand the forces. APT makes High Energy Impactors called the ‘RD15’ (up to 1.5tph) and the ‘RD50’ (up to 5tph).

Q: How much do the impactor bars wear?

A: The usual wear rate in APT RD’s is about 500 grams of bar per tonne of ore fed through the machine. This is about half of the wear rate in a ball mill for example, but because the bars only weigh about 9kg each in the RD15 and 18kg in the RD50, you need to replace the impactor bars every 8 hours os so.

Q: Is the cost of the bars very expensive?

A: The bars are manufactured so they cost more than the balls that go into a mill, but overall the cost of impacting including bar wear is about US$6 to US$10 per tonne, so it is just a small consumable cost to be taken into account.

Q: If I started off with an RD type gravity system, can I simply add a CIL cyanidation section?

A: No, you need to add a ball mill as well to reduce the size to 75 microns. This is not only necessary to maximise the gold dissolution, but also to prevent the sand from settling in the agitator tanks.

Q: What kind of gravity concentrators are there?

A: The simplest and least expensive is a sluice but the recovery is poor, especially for fine gold below about 150 microns. A sluice operates at 1 G force. Then comes the bowl concentrators. These are non-fluidised and operate at about 6G force. There are many models; APT makes the GoldKacha (up to 3tph) which has a deeper bowl and a reflux system to enhance fine gold recovery. Then there are the fluidized concentrators, which typically run at 60G force. The fluitized concentrators are more efficient but cost more too and also require clean water for fluidization. Examples are Knelson, Falcon and Icon. APT manufactures its own high G force fluidized concentrator called GK-X (10-15tph). We have designed the GK-X in such a way that it has many advanced features such as it is easy to use, clean and cheaper to buy and operate.

Q: How do I get the gold out of the gravity concentrate?

A: It the old days this was done with mercury amalgamation but this is no longer used as it is toxic to humans and the environment. APT uses a system whereby the concentrate from either the GoldKacha or the GK-X is first upgraded over a special concentrating table that has a bump-stop action. Typical models are the Gemeni and ST tables from South Africa. The table concentrate is now high grade and suitable for smelting with borax to get a gold button. If the concentrate is not high enough grade and if there is not enough gold, the smelt will not work. One solution is to accumulate table concentrates over several days and then put them over the table once more. But even then, you are not ready to smelt yet; the final stage is to dry the gold concentrate and then run a hand magnet over it to remove all the iron and magnetite. You then smelt with a mixture of concentrate and borax, 2:1 by volume, at 1200 degrees C. APT supplies the ST range of tables as well as electric muffle furnaces called P42 or P100 for large mines.

Q: How do I get the gold out of the carbon from the CIP or CIL system?

A: The pregnant carbon (loaded with gold) is placed into an elution column and hot cyanide and sodium hydroxide solution is pumped around through the bed of carbon. The solution dissolves the gold off the carbon and then flows through a series of electrowinning cells which plate the gold from the solution onto steel wool. The elution column and the electrowinning cells are in series so that the solution goes through both each time it is pumped around. The solution typically has 0.2% cyanide and 2% sodium hydroxide strength. The electrowinning section needs to work at about 4.2 Volts.

The elution process in an unpressurised (or open Zadra) type elution system that is used for small mines and needs a cycle of 2 days. If the elution system is pressurized (closed Zadra) this is reduced to 1 day, but these systems cost more and are more involved to operate and therefore are usually used by larger mines only.

Finally the steel wool with the gold on it is treated with nitric acid. This dissolves the steel wool and the remaining sludge is dried and smelted with borax to get a gold button.

  • CAUTION: All cyanidation processes (including elution) are potentially fatal if not performed properly. These processes should only be undertaken by qualified and experienced personnel and all safety procedures should be adhered to.

Q: How much gold do I need in the ore to be successful?

A: It depends upon many things, and the figures given below are just a general guideline. APT accepts no responsibility for the viability or otherwise of your project using these figures:

Small scale alluvial or elluvial up to 3tph Minimum recovery 3 g/t Au

Medium scale alluvial or elluvial 10-20tph Minimum recovery 2 g/t Au

Large scale alluvial or elluvial >50tph Minimum 0.6g/t Au

Small scale <10tph oxide ore gravity only Minimum 3.5g/tAu, add 1g/tAu for milling and cyanide

Medium scale <20tph oxide ore gravity only Minimum 2.5g/tAu, add 1 g/tAu for milling and cyanide

Large scale >50tph oxide ore gravity only Minimum 2g/t Au, add 1g/tAu for milling and cyanide

Small scale hard rock mill, CIL leach, <3tph Minimum 5g/t Au

Medium scale hard rock mill, CIL leach <20tph Minimum 4g/t Au

Large scale hard rock mill, CIL leach 20-50 tph Minimum 3g/t Au

Tailings grind and CIL leach, small scale <3tph Minimum 4g/t Au

Tailings grind and CIL leach, medium <20tph Minimum 3g/t Au

Tailings grind and leach, large scale 20-50 tph Minimum 1.5 g/t Au

APT Awarded Major Design Contract

I would like to extend a thank you to our valued client for their confidence in us. It will be a pleasure to execute this fantastic project and bring positivity to the industry.
— Mr K. Peacocke, CEO of Appropriate Process Technologies (APT)

APT has just been awarded the go ahead for the design phase of what will probably be the largest gold project to be awarded in South Africa in recent times. This exciting new project literally breaks new ground on a number of fronts and introduces the modular approach at a large scale.

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The Gold Price is Up: time to take advantage gold mining

As of today, the gold price is sitting at $1640 per ounce and is expected to go on the rise, something which is highly probable in today’s uncertain world. 

But here is something that is certain; there are abundant resources out there, be they surface rubble or process tailings, that are literally ready to be scooped up. You can also be certain that APT, with it’s lightning-fast reaction time, is ahead of the curve. We have specifically developed a number of products for rapid implementation. But we are as aware as you are that good revenues are one thing, but you still have to put the project together and find the seed capital to get it all started. Two new offerings have been specifically developed, one to treat rubbles and alluvial to recover gold and the other to treat artisanal tailings to recover both free gold as well as entrained amalgam. 

The Rubble system is based upon our infamous RG scrubber range and is titled the RG-B. This hardy workhorse has been combined with APT’s very own high centrifugal concentrator, the GK-X. As with all APT plants, this scrubber is a total in-house offering. As such, we have been able to trim down the design and the price with a 15-20tph plant coming in at less than US$150 000!  At around US$7000 per tonne per hour capex, this is probably the lowest process establishment cost out there today, and at around US$2 per tonne the opex cost is definitely amongst the lowest possible. There is also a smaller version of the rubble plant available in the 6-10 tonne per hour range which hosts the same benefits, including short lead times and speedy on-site manufacture and commissioning.

The 10-15 tph tailings treatment system offers a simple ready solution to the huge resource of tailings that the Artisanals have left behind. These tailings have already been ground and require simple slurrying and the removal of the odd errant oversize like bricks etc. The Tailings Plant slurries the loose material ahead of feeding to the same high efficiency GK-X concentrator, simple yet effective and devoid of moving parts other than the concentrator itself. The plant is compact and easy to translocate from place to place. At less than US$40 000 for this system the capex per tonne per hour is less than US$3 pet tonne, and opex is likewise extremely trim.

Both systems are available on extremely short delivery basis, ready for you to take advantage fast.

Elu-X: the open zadra elution system

APT’s Elu-X is a new product in the APT range that compliments the APT TriTank CIL and CIP plant systems. The Elu-X is an open Zadra elution system that strips the gold off the loaded carbon that is produced in the TriTank plants and this completes the process. To keep these small scale systems as safe as possible, the Elu-X is non pressurized and thus operates just below boiling point. The result is that an elution cycle lasts typically two days, but the capacity of the units is designed to accommodate this. The advantages of the Elu-X is that it’s geometry is designed to get the maximum reaction activity due to the optimal height to diameter ratio. The entire unit is manufactured from stainless steel and is fully cladded for thermal efficiency. Pump-around is achieved via a totally sealed magnetic drive pump so no annoying pump and piping leaks occur. The gold, once stripped is won from solution in APT’s proprietary ‘kebab’ electrocells, especially designed for this purpose.

The Elu-X seen here in manufacture at our Head Office in Johannesburg, South Africa

The Elu-X seen here in manufacture at our Head Office in Johannesburg, South Africa

This elution system truly a top quality product at an affordable price. As always, feel free to contact us here for further information.