Social:Automated conveyor roller condition monitoring
Automated conveyor roller condition monitoring is an emerging field that has risen out of the need to make bulk handling conveyors more reliable. Belt conveyor systems are widely utilized for continuous transport of dry bulk materials (i.e. coal, iron ore) over varying distances. A vast variety of industries like the mining, power sector, cement production, and bulk terminals rely on the performance of belt conveyor systems. Compared with other bulk haulage modes like the trucking and railway, belt conveyor systems provide many advantages such as a higher capacity, lower cost, higher efficiency, less human involvement and proven reliability (Roberts, 1981; Smith and Spriggs, 1981).[1]
Along with the growing international trade in major bulk materials, there is an increasing demand for the transportation of bulk materials. Correspondingly, large-scale belt conveyor systems have been installed to meet the demand for higher capacity and longer distance application of continuous conveying of bulk materials (Harrison and Roberts, 1983; Lodewijks, 2011). [2]
The downtime of belt conveyor systems leads to stoppage of transportation of bulk materials, influencing subsequent material processing and production, and consequently causing serious financial loss. In a mining plant, for example, sixty percent of the plant downtime was attributed to conveyor problems (Steinberg, 1983). The downtime cost of belt conveyor systems may vary from one application to another. The financial loss due to the downtime of belt conveyor systems can be in a range of 100,000 to 200,000 Euro per hour, considering the loss of the revenue from material conveying, and shutdowns of subsequent material processing facilities (Lodewijks, 2015).[3]
Conveyor production delays and reliability issues are generally a result of a failure in one of the three main components of a conveyor system. The belt, drives/gearboxes or the conveyor rolling elements. Of which – Conveyor idlers are the most numerous component on the conveyor system. It has been shown that conveyor roller failure in underground coal mines is the premier cause of fires. This presents a significant hazard to coal mine workers.[4]
Inspection methods
Internal to the roller
Vayeron is an Australian based company that has developed a hardware sensor device which is designed to be embedded within the conveyor roller itself.[5] The Smart-Idler™ is an automated conveyor roller condition monitoring & prognostics technology that is embedded within conveyor rollers when they are manufactured. The device monitors bearing temperature, vibration, acoustics and roller shell-wear to predict conveyor roller failure. This ultimately makes conveyor roller condition monitoring more efficient and reduces operational downtime.[6] The Smart-Idler™ sensor operates without batteries, taking its power directly from the rotation of the conveyor roller, using a dynamo style energy harvesting method as it turns whilst in operation within the conveyor. Companies that make conveyor rollers can integrate the Smart-Idler™ within their conveyor roller products to create an enhanced roller offering for their clients - the owners and operators of conveyor systems. The embedded sensors have a multi-modal monitoring capability. Parameters such as bearing temperature, vibration, acoustics and roller shell wear are monitored and analysed to determine roller condition deterioration and flag impending failure.[5][7][8]
External to the roller
Externally mounted monitoring technologies are also being investigated by the industry. Largely showing mixed results of success, these proposed technologies are mostly research based initiatives. A complexity arises out of detecting specific failing rollers using generalised monitoring technologies such as optic fibre cables or vibration monitoring transducers mounted to the conveyor frame. The general, non-specific nature of these technologies have many issues similar to those encountered with the traditional monitoring aids used by inspection personnel. Acoustic monitors, Infrared cameras and any other technology that does not monitor the rollers in a holistic way, generally fail to accurately predict impending roller failure. This is because conveyor roller failure is multi-modal and is indicated over a variety of failure signals not solely identified using single mode detection systems which are characteristic of optic fibre or vibration transducers mounted to the conveyor structure.[9]
Economic benefits of conveyor roller monitoring automation
Increased asset utilization
Increased production levels are the key driver for most improvement projects. The operating profit from increased production levels is extra cash flow entering the business.[10]
Maintenance cost control
The improvement project can focus on decreasing the maintenance cost through more efficient operation.[10]
(Non-human) resource allocation
Enhanced inventory control or reduction in overall inventory on site due to the targeted nature of automated conveyor roller monitoring systems will generates large operational savings for the business. A more efficient and focused spare parts management, process could result in less associated business running costs. Also, improving particular equipment such as the conveyors could increase the equipment lifetime, and as such, delay future equipment replacement costs. Therefore, reducing the components total cost of ownership (TCO).[10]
Human resource allocation
In the case of adapting a more maintenance conducive technologies and strategies, fewer personnel may be required.[10]
HSE compliance
Companies must comply more and more with Health, Safety and Environmental (HSE) regulations. This can result in negative cash flows from high penalties and/or loss of a license to operate.[10]
References
- ↑ [X. Liu, Prediction of Belt Conveyor Idler Performance, Dissertation, Delft University of Technology, 2016, pg. 1]
- ↑ [X. Liu, Prediction of Belt Conveyor Idler Performance, Dissertation, Delft University of Technology, 2016, pg. 1]
- ↑ [X. Liu, Prediction of Belt Conveyor Idler Performance, Dissertation, Delft University of Technology, 2016, pg. 1]
- ↑ [Fernandez, M., Rodriguez, A., Pruchnicka, J., Hoischen, U., Wojtas, P., Gonzalez, J., and Cole, J. Early detection and fighting of fires in belt conveyor. Technical report, European Commission: Luxemburg, 2013. Page 16]
- ↑ 5.0 5.1 Probert, Oliver. "Aussie start-up creating a smarter idler roller". Bulk Handling Review. https://bulkhandlingreview.com/aussie-start-up-creating-a-smarter-idler-roller/. Retrieved 8 June 2017.
- ↑ http://www.vayeron.com.au
- ↑ [Liu, X., Lodewijks, G., and Pang, Y. Intelligent maintenance of large-scale belt conveyor idler rolls: State-of-the-art and opportunities. In Proceedings of the 1st Symposium on Automated Systems and Technologies, Hannover, Germany, 2014a. page 88]
- ↑ https://bulkhandlingreview.com/flippingbook/2016/March-April/index.html#20
- ↑ [Pang, Y. Intelligent belt conveyor monitoring and control. Phd thesis, Delft University of Technology, 2010.]
- ↑ 10.0 10.1 10.2 10.3 10.4 Thieme, K.R. Economic justification of automated idler roll maintenance applications in large-scale belt conveyor systems. Technical report, Delft University of Technology, 2014. Page 66-67