The disclosure relates to an accelerator disc for a disc stack separator and a disc stack separator using such accelerator disc.
A disc stack separator consists of a feed pipe for a suspension or solid/liquid mixture, a stack of filter discs, an accelerator disc and a bowl. The solid/liquid mixture is directed by the feed pipe to a so called accelerator disc which directs the mixture into the rotating bowl. The accelerator disc has the form of a cone with its top pointing upwards towards the feed pipe and fitting underneath the stack of filter discs. While the feed pipe is stationary, the accelerator or accelerator disc and the bowl rotate normally at a speed of up to 15,000 rpm. In the disc stack, which is also rotating, the mixture is separated into a light fraction and a heavy fraction, which may include solid particles. The whole mixture is transported by a feed pipe into the accelerator. The light and heavy fraction are separated and moved through the accelerator by the centripetal pumps to the outlet.
The heavy fraction will be discharged from the periphery of the bowl at regular time intervals.
The heavy and light fraction is transported by the centripetal pumps through channels in the rotating shaft upwards and discharged through a discharge pipe. The heavy fraction is discharged through nozzles in the wall of the bowl in case of a nozzle separator. Due to the rotation, the light fraction concentrates in the centre and the heavy fraction is sent to the circumference.
Accelerator discs are used in the state of the art to distribute the flow of suspension or a mixture to the filtering area like a stack of filter discs. The disclosed embodiments are useful to eliminate the drawbacks of the state of the art and provide an accelerator disc for a disc stack separator with reduced energy consumption. This is achieved by utilizing blades of the accelerator disc that are curved. With such a configuration the flow can be directed to the space for the nozzles in the disc stack separator bowl already in an optimal manner.
A further favourable embodiment is characterized in that the blades are curved counter to the direction of rotation. This allows use of the energy of the flow without any slowing down, and thus reduces the necessary energy for the transport of the suspension or mixture, and thus reduces the overall power consumption of the instrument. This is especially of use with suspensions with high specific gravity, e.g. up to 2.0 g/l (kg/m3).
Another advantageous embodiment is characterized by additional blades extending only along a part of the surface of the accelerator disc and being arranged between blades extending along the whole surface, whereby the additional blades extending only along a part of the surface may have a wider profile than the blades extending along the whole surface of the accelerator disc. These additional blades allow the distribution and transport of a considerable amount of suspension and thus the throughput can be increased considerably.
The disclosure is also related to a disc stack separator, and especially a centrifugal nozzle separator. The inventive disc stack separator is provided with an accelerator disc like that described above.
The disclosed embodiment are now described in detail with regard to the drawings where:
In
Embodiments of the disc 3 have up to 50 blades.
Although the present disclosure has been described and illustrated in detail, it is to be clearly understood that this is done by way of example and not limitation. So the angle of the curved blades can be quite different for the material to be treated and the concentration of the suspension or mixture.
Number | Date | Country | Kind |
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16201461.7 | Nov 2016 | EP | regional |