An electricity tariff increase of almost 10%, announced at the beginning of March 2016 has put further pressure on the industrial sector – and underscored the importance of energy efficiency in all aspects of company operations.
Variable speed drives (VSDs) have proven to be one of the most effective ways of reducing power consumption of motors, which reportedly account for about two-thirds of industrial electricity usage. Additional and significant reductions in consumption can be attained through ensuring that VSDs are installed with ‘backchannel cooling.’
“An innovative technological application which is being led in South Africa by RTS Africa Engineering,” says the company.
Back-channel cooling offers a cost-effective way of ensuring that the temperatures within VSDs do not reach levels which risk shortening the life of these devices. The drives are often located in machine control centres (MCCs) or similar locations which provide appropriate protections, but may become very hot through the combined effects of ambient temperature and the heat generated by VSDs.
Traditionally, site engineers have coped with this problem by installing large air conditioners that cooled the air in MCCs. With backchannel cooling, however, ambient air from outside the control centre is channelled through a VSD, over the heat sink of the device, then vented out from the MCC.
“The critical point here is that the channelled air does not have to be cooled. The steady flow of air over the heat sink keeps the VSD at ambient temperature, which is normally quite acceptable: the drive does not actually need to be kept at a cooler temperature,” explains Ian Fraser, Managing Director of RTS Africa Engineering.
“Up to 85% of the heat generated by VSDs is dispensed with through back-channel cooling, cutting down on the need for air conditioning. This translates into savings that can prove astonishing. Air conditioners are very energy-intensive, and they can be unreliable in harsh environments,” Fraser advises.
Air flow is driven by a fan and passed through inertial spin filters, which address another key challenge of MCC environments: the build up of dust. The spin modules used by RTS Africa Engineering remove 98% of particles measuring 15 micron (μm) or larger; while dust arrestance at 5μm is 80%. As the modules make use of cyclone technology to capture dust (rather than filters which regularly become clogged) and are also self-purging, they require little maintenance.
This provides further savings to the user, who also benefits from the fact that the modules – manufactured from high-density polypropylene – are exceptionally durable. In certain instances, spin filters installed by RTS Africa Engineering have been operational for more than 20 years.
This more than repays the initial cost of investment in the filters, which may be higher than that of competing products. The very simplicity and ingenuity of spin filter technology have sometimes proved an obstacle to its acceptance.
“In the beginning, nobody believed it would work. However, word gets around, and our track record now speaks for itself,” Fraser adds. RTS Africa Engineering has supplied spin filter technology to several key mines in South Africa and pan-Africa. The company is now seeing increasing interest in spin filters from other industrial sectors, and also from international enquiries. Currently, they are installing filters at a leading steel manufacturer where “dust loading is a real challenge,” notes Fraser.
While enquiries about the technology have come from Australia and India – markets that he believes hold great possibilities.
“I believe we have taken this technology much further than anybody else locally has,” says Fraser.
“Clients come to us with complex filtration and ventilation challenges, and we work hard to find them a viable, sustainable and affordable solution. We purpose-build the technology, and it is not a standard product – it is all custom-designed. If it is possible to engineer it, we will do it,” Fraser concludes.