A Process is essentially a series of operations, which are interconnected, with the performance of one operation affecting the performance of another. Optimising each stage separately without considering the whole system often causes potential economic benefits and savings to be missed. It is crucial for information sharing to occur across operations to ensure access to real time information.
Because of the frequency of incidents of lost, misidentified or unidentified samples as well as the quantum of lost time associated with manually tracking and tracing the requisite samples, the capacity of the Geology function is unable to match that of the Mining function resulting in periods of “Blind mining”.
Controlling ore loss and dilution is critical for most mining operations. Getting it wrong can result in millions of dollars per year of lost revenue.
Two of the most important issues mines have to deal with are tracking the ore mined from pit to plant and to test the efficiency of beneficiation equipment. A key issue is that of waste being transported to the crusher and ore being transported to waste. There are various reasons for this ranging from the loss of or incorrect assignment of survey data, to the shifting of the block during blasting, to errors on the part of dispatchers and shovel operators, and being unable to identify the ore grade during hauling and ore transfer
In order to drive productivity through innovation by linking resource and downstream processing, RFID Institute has developed the GCMS® System based on RFID technology which tracks material before and after the blast. Blast Movement Technologies (BMT) has developed hardware and software - Blast Movement Monitoring (BMM®) System – for measuring movement of the ore during the blast. The combination of these two systems results in increased knowledge of ore body characteristics and behaviour having the potential to efficiently manage ore and optimise the entire mining cycle.
1.Holes are planned, requested and drilled by mining.
2.A number of BMMs are then installed in dedicated blast holes within the blast and surveyed. The Activator is a remote control that switches each transmitter on and programs it as required.
3.A special detector is used to locate the BMMs after the blast and calculate their depths. BMM X, Y, Z co-ordinates are surveyed.
4.Included software calculates the 3-dimensional movement vector of each BMM. The data is sent to the GCMS® database for future reference.
5.Ore boundaries or digging levels can then be redefined within 1-2 hours of the blast to reflect the measured movement, and hence reduce ore loss and dilution. The post blast dig lines are then made available and displayed in the GCMS® System.
Because of the frequency of incidents of lost, misidentified or unidentified samples as well as the quantum of lost time associated with manually tracking and tracing the requisite samples, the capacity of the Geology function is unable to match that of the Mining function resulting in periods of “Blind mining”.
Two of the most important issues mines have to deal with are tracking the ore mined from pit to plant and to test the efficiency of beneficiation equipment. A key issue is that of waste being transported to the crusher and ore being transported to waste. There are various reasons for this ranging from the loss of or incorrect assignment of survey data, to the shifting of the block during blasting, to errors by dispatchers and shovel operators, and being unable to identify the ore grade during hauling and ore transfer.
1.Identify areas to be seeded within the block.
2.Register Ore Tracers with block, row, hole and grade data.
3.Seed Ore Tracers within production holes.
4.Blast!
5.Shovel reader auto read hauler ID. GCMS® will marry grade / waste to hauler ID.
6.Tip reader auto read hauler ID. Log / Alert. Auto read Ore Tracers at tip.
7.Auto read Ore Tracer grade at feed to buffer stockpile and buffer stockpile discharge.