Sandvik 5 Inch Re040 Re542 Re543 Re545 RE054 RE547 PR52 PR54R Reverse Circulation RC Drill Bit

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Sandvik 5 Inch Re040 Re542 Re543 Re545 RE054 RE547 PR52 PR54R Reverse Circulation RC Drill Bit




Reverse Circulation (RC) drilling is used to collect mineral and rock samples quickly and efficiently using a large rotary drill and air compressor. Reverse Circulation (or RC) drilling is one of the most frequently used methods of drilling used across the world as it is more cost effective and efficient then other methods of drilling. When compared to RAB (Rotary Air Blast) and diamond drilling, RC drilling seems to be somewhere in the middle when it comes to cost, time, quality of samples, technique and depth.



Applications:
RC drilling is a technique used in the majority of stages of mine development.
As it is cheaper than diamond core drilling, it is often used in first stage exploration mining to delineate a potentially extractable ore body. It is also preferable to RAB or air-core drilling when trying to reach great depths, but RC drilling is slower and more expensive than either of these two methods.
RC drilling is also consistently used during in-pit grade control and the development stage of an ore body.



 

Basics of Reverse Circulation Drilling:

(1) RC drilling uses rods with inner and outer tubes, the drill cuttings are returned to surface inside the rods. The drilling mechanism is a pneumatic reciprocating piston known as a hammer driving a tungsten-steel drill bit.
(2) RC drilling utilizes much larger rigs and machinery and depths of up to 500 meters are routinely achieved. RC drilling ideally produces dry rock chips, as large air compressors dry the rock out ahead of the advancing drill bit.
(3) RC drilling is slower and costlier but achieves better penetration than RAB or air core drilling; it is cheaper than diamond coring and is thus preferred for most mineral exploration work.
(4) Reverse circulation is achieved by blowing air down the annulus of the rod, the differential pressure creating air lift of the water and cuttings up the inner tube which is inside each rod. It reaches the deflector box at the top of the drill string then moves through a sample hose which is attached to the top of the cyclone.


The drill cuttings travel around the inside of the cyclone until they fall through an opening at the bottom and are collected in a sample bag. For any drill hole there will be a large number of sample bags, each one marked to record the location and drilling depth that the sample was obtained.

The collected series of sample bag cuttings are later taken for analysis to determine the mineral composition of the drill hole. The analysis results of each individual bag represents the mineral composition at a particular sample point in the drill hole. Geologists can then survey the drilled ground analysis and make decisions about the value of the overall mineral deposit.

Advantages of Reverse Circulation Drilling: 

Compared to core drilling, RC drilling with inherently faster penetration rates provides several benefits:

1. Direct drilling cost reductions in the range of 25% to 40%.

2. Faster completion of drill programs with quicker delivery of results.

3. Reduced man-hours at the drill with decreased exposure to potential accidents.

4. Reduced contractor activity in the mine reduces mine support burden.

5. Indirect cost reductions gained from a simplified sampling process.

6. Requires less water than diamond drilling.


RC samples are collected at the drill and sent directly to the assay lab. Unlike diamond drill core, which is generally logged, photographed, split for sample, assayed and warehoused, RC sampling requires much less handling resulting in faster assay turnaround with accompanying cost reductions. Larger volume RC samples often give more representative gold samples than split half core samples. 
 

Hammer Model Hole Range (mm) External Diameter (mm) Length (without bit) mm Connection Thread Working Pressure
RE531 84-100 81 1069 3" Remet 1.0-3.0Mpa
RE004 111-127 107 1252 3.5-4" Remet  1.0-3.0Mpa
4" Metzke
RE542 113-130 109.5 1191 3.5-4" Remet  1.0-3.0Mpa
4" Metzke
RE543 120-135 116 1191 3.5-4 Remet  1.0-3.0Mpa
4" Metzke
RE545 122-135 117.5 1261 4-4.5" Remet  1.5-3.5Mpa
4-4.5" Metzke
RE547 130-146 124.5 1270 4.5" Remet  1.5-3.5Mpa
4.5" Metzke
PR40 124-142 120.5 1362 3.5-4.5" Remet  1.5-3.5Mpa
3.5-4.5" Metzke
PR52 126-142 121 1227 4-4.5" Remet  1.5-3.5Mpa
4-4.5" Metzke
PR52R 130-146 124 1225 4-4.5" Remet  1.5-3.5Mpa
4-4.5" Metzke
PR54 135-150 130 1294 4.5" Remet  1.5-3.5Mpa
4.5" Metzke
MX5456 136-150 132 1362 4.5" Remet  1.5-3.5Mpa
4.5" Metzke
RC62/RC62R 152-190 146 1320 As Request 1.5-3.5Mpa
RC82/RC82R 190-250 180 1395 As Request 1.5-3.5Mpa
RC100/RC100R 250-370 240 1528 As Request 1.5-3.5Mpa

 

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