MILLING CONTROL & OPTIMISATION MillSTAR
OVERVIEW Due to the complex nature of milling circuits, it is often found that conventional control does not address many of the common problems experienced. These include: Long process response times. Multivariable interactions and disturbances. Non-linear systems with varying dynamics. Constraints on variables. Lack of reliable process measurements. The Millstar Advanced Control System has a comprehensive suite of control strategies that can be applied to provide an innovative control solution for almost any milling circuit configuration. The main goals are: Stabilise the mill feed. Control product quality to the downstream processes. Optimise throughput and grinding efficiency. Provide a robust control solution. User Interface Millstar Power Optimiser, Segregated Ore Controller Millstar Mill eed Control Millstar Product Quality & Discharge End Control. Millstar MPC Millstar Specialised Surge Tank Control Millstar Particle Size Estimator Millstar Mill Discharge Density Estimator Millstar Ball Load Estimator Millstar Mill Power ilter Optimisation Stabilisation Estimators Intelligent iltering and ault Detection for Level Signals, Density, Size, low and Pressures ault Detection and Signal Conditioning Plant Plant Control Plant Instrumentation OVERALL MILLSTAR BENEITS Maximises throughput. More consistent feed to downstream processes, thereby increasing recovery. Optimal usage of mills. Individual customisation. Improved control of mill feed rate. Better management of fine and coarse material, thereby preventing mill overloads. Prevents violation of constraints, making daily operation easier. Robust control solutions for effectively handling instrumentation failures. boasts a typical payback period of just a few months. RESEARCH Mintek enjoys a proud history of research in the minerals processing industry and is continually striving to expand its knowledge in the field through: Partnerships with Industry Inter-divisional collaboration within Mintek (Minerals Processing, Mineralogy, etc.) University interaction
MATERIALS HANDLING MILL EED CONTROL Smooth operation of a milling circuit is difficult to achieve due to: The varying nature of the feed material (size, ore hardness, etc.). The unfavorable dynamics between feeders and the weightometer. These dynamics degrade the performance of PID controllers, making feed optimisation more challenging. Silo Silo eeders Mill s Mill eed Controller will: Compensate for the feed dynamics by modeling feeder responses. Adapt for any model errors. Adjust the feeder speeds in a desired ratio. The graph on the right (igure 2) shows a comparison between PID control and s eed Controller for the plant illustrated in igure1. It is clear that setpoint tracking is much tighter and faster under control. Mintek s control solutions are extremely flexible and can easily be adapted for other applications. or instance, the mill feed controller has been used to stabilise and optimise the operation of a Crushing Circuit by overcoming the following challenges: Multiple feeder and weightometer system. Variable time delay in process responses. requent belt trips due to limits on power draw of belt feeders. The Mill eed Controller was combined with Mintek s safety controllers to achieve the following: (See igure 3) Effectively stabilise the mass flow through the crushing circuit, which improved screen performance and thus increased throughput and reduced circulation load. The safety controllers prevented belt trips by selecting the correct operating conditions. Tighter control enabled the plant to be pushed closer to its limits. An increase in throughput of 4% was obtained. Throughput mass flow average (t/h) Throughput mass flow standard deviation (t/h) Circulating mass flow average (t/h) Circulating mass flow standard deviation (t/h) O 389 94 969 141 ON 43 73 916 128 % Improvement 4% 22% 5% 9% Solids flow 6 4 (4 SEC) Time Delay igure 1: Example of typical Time Delay on Mill eed 85 8 75 7 65 6 5 8 75 7 65 6 5 Solids eed Control - PI Controller 5 minutes Solids eed Control - Mill eed Controller Mintek Crushing Control O 1 minute 13:42 13:44 13:46 13:48 13:5 13:52 13:54 13:56 13:58 14: 14:2 14:4 14:6 14:8 Time igure 2: Comparison between PID control and s eed Controller Mintek Crushing Control ON Throughput Mass low 2 2 1 eeder Speeds 5 1 15 2 25 3 35 4 Time (seconds) igure 3: Mintek Crushing Control 5 4 3 eeder Speed (%)
SEGREGATED ORE EED CONTROL (eed Ratio Optimisation) On milling plants fed by a segregated feed supply, such as a stockpile, the varying size and hardness of the mill feed material affects the residence time in the mill and the power drawn. When the load becomes critically high, the feed needs to be cut in order to grind the mill out. This dramatic change in mass flow and particle size is passed to the downstream processes, causing recovery to be compromised. Calculate Ore Coarseness s Segregated Ore eed Controller is designed to: Prevent mill overloads. Adjust the coarse and fine feeder ratios to make optimum use of the ore supply and limit the need to grind the mill out. Interact with operators rating of the coarseness of each feeder to determine the size distribution of feed material. Use advanced model-based techniques to reduce variation in the feed and thus enable increase in average throughput by operating closer to limits. Integrate with visual or other rock-classification systems. Coarse ine Coarse eeder Speeds Segregated eed Controller Adjust total Ore Coarseness igure 4: Segregated eed Controller Load or Power THROUGHPUT OPTIMISATION POWER OPTIMISATION or the most productive milling operation it is often best to operate close to the maximum mill power draw. The power-load relationship is highly non-linear and shifts around as the ore and steel load/liner changes. Traditional control and modeling techniques can therefore not be used. Mintek has developed a Power Optimiser that: Power (kw) 1 9 8 7 6 Increase Solids eed Under-loaded so increase Solids eed Increase Solids eed Over-loaded so decrease Solids eed 5 1 2 3 4 5 6 7 Continuously seeks for the optimum mill operation by changing the solids feed or load setpoint. Uses the changes in the mill load and power to automatically detect whether the mill is overloaded or underloaded. Uses safety controllers to change the solids feed rate and feed water to prevent mill overloads. Estimates the power load curve and optimum load. By optimising the mill power usage and preventing mill overloads, significantly increases in throughput from 6 to 16% have been achieved. Power Power Optimiser Power H/L Load Load H/L Safety Controllers Load (%) igure 5: Typical Power/Load curve Segregated Ore Controller Solids eed Rate Ratio Mill eed Water eed Ratio eeder Speeds Plant RECIRCULATING LOAD OPTIMISATION igure 6: Mill Optimisation Control Strategy By optimising the recirculating load it is possible to maximise the possible throughput of the milling circuit. The Recirculating Load Optimiser dynamically adjusts the recirculating load to ensure optimum efficiency of the circuit based on operator-specified constraints. This strategy is particularly beneficial for overflow mills.
Case Study 1: igure 7 shows data collected from a platinum plant, where the ore treated was very difficult to mill. In the first two days, the mill experienced numerous power dips (overloads), and on at least seven occasions the feed to the mill had to be completely stopped to grind the mill out. Also, the mill load varied in the range of 125 to 165 tons. These disturbances propagated throughout the milling circuit and even to the flotation circuit. The Millstar Power Optimiser gave the following benefits: Mill feed cuts were prevented, resulting in a stable mill loading. No huge power dips occurred, since any sign of the mill overloading was detected and rectified timeously. The standard deviation of the mill load, flotation feed flow and density was considerably less in mode, as can be seen in the table below. A significant increase in throughput of 15.5t/h on average (about 1% increase). Mill eed(t/h) & Load(t) Power Optimiser On/Off Data (with a consistent ore source) O ON 3 18 25 Mill Overloads 16 14 2 12 15 1 8 1 6 5 Mill eed Cuts 4 2 DAY 1 DAY 2 DAY 3 DAY 4 Power(kW) Mill eed PV Mill eed SV Mill Load Power igure 7: Mill Power Optimisation results for Case Study 1 O ON % Improvement Mill Throughput Average t/h miled 16.42 175.95 1 Mill Load Mass low to lotation (t/h) Case Study 2: igures 8 and 9 on the right show results from a gold plant s SAG mill achieved with s Segregated Ore eed Controller combined with the Power Optimiser: The standard deviation of the mill feed control is greatly reduced. The cyclone feed is more stable, allowing for consistent size separation and feed to downstream processes. Due to the tighter control the feed setpoint can now be set closer to its maximum operating limits with confidence. eed Rate (t/h) Cyclone eed Pressure (kpa) Cyclone eed low (m3/h) Std Dev Minimum Maximum Std Dev Std Dev Cyclone eed Density (SG) 32.6 185 7.21.627 O 56.57 9.72 64.16.9 17.25 185 3.91 Standard Deviation ON 19.41 5.11 52.1.1 46 42.363 42 % Improvement 65.7 47.4 18.9 84.3 5 4 3 2 1 4 3 2 1 % of Total Data Points O 3 6 9 12 Time (min) 5 ON 3 6 9 12 Time (min) 35 3 25 2 15 1 5 35 3 25 2 15 1 5 Comparison of Plant vs Mill eed Control 4 318t/h 35 299t/h 3 25 2 15 1 5 1 2 3 4 5 eed Rate (t/h) O ON Power(kW) Power(kW) Mill eed PV (t/h) Load (t) Mill eed SV (t/h) Load SV Cyc Pressure (kpa) Power (kw) Cyc low (m3/h) igure 8: Mill Power Optimisation results for Case Study 2 igure 9: eed Control Distribution for Case Study 2
MILL DISCHARGE PRODUCT CONTROL THE MILLSTAR SUMP/PRODUCT STABILISATION OCUSES ON: Taking into account multivariable interactions between input and output mill discharge variables. Controlling the sump level and cyclone overflow product size and/or density. Minimising flow variation to the downstream processes. Optimum usage or surge capacity of sumps, hoppers and conditioning tanks. Handling constraints of the sump level (to prevent pump surging and spillage) and cyclone density (to prevent pipeline chokes and pressure variations). Mill Sump Water L MPC D Screen Cond Tank MPC Minimise Mass low Variation L D To lotation Mintek has developed a Model Predictive Controller (MPC) specifically for controlling milling circuits, with the following advanced features: ully fledged multivariable controller that can efficiently eliminate interaction between variables. Explicitly handles limits on input and output variables to ensure all variables are kept within their allowed operating range. Very efficient in handling long time delays and slow-reacting processes. Special features to handle noise, integrators and model errors. Case Study 3 Data collected from a platinum plant is shown on the right (igures 1 to 12). The feed to flotation in terms of volume flow and density (mass flow) is much more stable in mode. lotation eed low (m 3 /h) lotation eed (SG) Mass Low (t/h) O 15.77.17.169 Standard Deviation ON 2.77.48.13 % Improvement 82 92 igure 1: Example of Mill Discharge Circuit showing MPC Controller Mill eed (t/h) Sump eed (Water m3/h) Sump Disch SG Surge Level (%) loat eed SG 24 22 2 18 16 14 12 1 4 35 3 25 2 15 1 1.6 1.5 1.4 1.3 1.2 9 75 6 Stabiliser ON/O Data using MPC Stab ON Stab O Stab ON 3 1. 1.42 1.39 1.36 1.33 1.3 1.16 11.57 13.37 15.18 16.59 18.4 2.21 22.1 Time igure 11: MPC results for Case Study 3 24 22 2 18 16 14 12 1 8 75 7 65 6 5 4 4 35 3 25 2 15 4 35 3 25 1.5 1.5 Mill eed (t/h) Sump Level (%) Sump Disch low (m2/h) loat eed low (m2/h) Auth Stabilising the product quality from the milling circuit leads to improved recovery downstream. In the case of flotation processes, improvements of between.5 and 1.5% in recovery have been shown. On gold leaching circuits, will minimise grind size while still maintaining throughput targets. This leads to considerable reduction in residue grinds. CYCLONE SWITCHING CONTROL Clusters of cyclones are often used for mill discharge classification. By controlling the number of open cyclones the pressure within the cluster can be controlled. Stabilising the pressure improves the stability of the cyclone overflow particle size and density, which improves the consistency of the feed to the flotation. The module can also balance cyclone usage and, if required, estimate the cyclone's state (open/closed). % of Total Data Points 4 35 3 25 2 15 1 5 -.6 loat eed SG - Error from Setpoint.3t/h.3t/h -.4 -.2.2.4.6 Error from Setpoint O ON igure 12: lotation eed SG for Case Study 3
MILLSTAR ESTIMATORS MILL DISCHARGE DENSITY ESTIMATOR (MDDE) The MDDE estimates the mill discharge density and flow using dynamic volume and mass balances. An energy balance can optionally be performed to enhance the accuracy of the estimate. Grinding efficiency is highly dependent on the viscosity of the material within the mill, which correlates closely with the density, The calculated density can therefore be controlled by changing the amount of water added to the mill, to ensure optimum grinding. PARTICLE SIZE ESTIMATOR (PSE) Mill D Sump Water L D MDDE The PSE is a soft sensor capable of accurately predicting the particle size of the hydrocyclone overflow product. It has the following features and uses: 6 igure 13: Mill Discharge Density Estimator The PSE uses an empirical model, identified from extensive plant testwork. It can be used as a back-up sensor for a physical size measurement device. It can provide a continuous estimate of the particle size in-between slow updating or multiplexed measurements. When a size measurement is available, this information is automatically used by the PSE to continuously adapt the model. The PSE can also serve as an intelligent filter that eliminates the delay associated with physical measurements by inferring the particle size from measurements that have much shorter delay times. MILL POWER ILTER An accurate mill power measurement is essential in ensuring reliable control of a milling circuit. It can also give useful information about the load in the mill. The power measurement is, however, cyclical in nature and quite noisy. While conventional filters fail to separate actual process variations and process noise effectively, the Mill Power ilter succeeds by using high-frequency data and a sophisticated filtering algorithm. The result (as shown in ig. 15) is a smooth power signal suitable for control and immune to noise and cyclical variations. AULT DETECTION completes and complements its control suite with a range of fault detection and signal conditioning tools that can be used in conjunction with expert rules to timeously detect instrumentation failure and take necessary action to ensure smooth operation. STEEL BALL ADDITION MODULE Particle Size (% - 75 ) Power (kw) 5 4 35 18:4 18:18 18:33 18:47 19:1 19:16 19:3 Time Size Measurement PSE igure14: The graph above shows how well the PSE tracks the real particle size measurement. Note how it can be used to eliminate spikes and noise in the measurement. 9 8 7 6 5 4 3 2 1 5 1 15 2 25 3 Time (seconds) Raw Power irst Order ilter Mill Power ilter igure15: Power ilter result Estimates the steel ball load in the mill. Reminds operators of steel ball additions at pre-defined intervals. Displays steel ball addition history. Suggests the amount of steel balls that should be added, based on ore characteristics and changes. Can be linked to an automated ball addition system to control ball addition.
Contact Details: Website: www.mintek.co.za/millstar.html or www.starcs.co.za email: millstar@mintek.co.za Tel: + 27 ()11 79 4379