The invention relates to a decanter centrifuge with a rotating bowl provided with at least one solids discharge port and at least one clarified liquid discharge port and a screw conveyor disposed coaxially within said rotating bowl so as to be included in said rotating bowl rotated in the same direction with a differential rotational speed, where a feed suspension to be separated is introduced into a ring shaped space formed between said rotating bowl and said screw conveyor through a central feed pipe fixed to the end of the screw conveyor and supported in at least one bearing and can be separated by centrifugal force into a solid and a liquid phase so that said solid phase is discharged from said solid discharge port and said liquid phase is discharged from said clarified liquid discharging apparatus, whereby a liquid phase conduit is arranged in the shaft guiding the liquid phase outside of the bearings, a liquid phase valve provided outside the bearing on the side facing away from the bowl and screw.
A decanter centrifuge in the state of the art is shown in EP 0 447 742 A2 where the solid discharge port is arranged at the inside of the feed pipe end bearing. The liquid discharge port for the clarified liquid is on the side of the end plate connected to the drive shaft of the bowl and is equipped with a weir, which can be adjusted in its height by an adjusting weir board.
As the drive shaft has to have a certain diameter, usually in the range of the screw shaft, the liquid outlet can only be a great distance away from the axis. This leads to high energy consumption. Also JP 2002 336735 shows a decanter centrifuge with a rotating bowl and rotating screw with a liquid phase conduit arranged in the shaft with a discharge valve.
The goal of the invention is thus a reduction of power loss from accelerated liquids and solids by reducing the discharge radius to an absolute minimum.
This is achieved by a sealing at the end of the feed pipe and the liquid phase valve being adjustable during operation of the decanter centrifuge. As the feed pipe has a small diameter with regard to a usual drive shaft and the clarified liquid is discharged via a conduit around the feed pipe, the energy consumption is very low.
A further embodiment of the invention is characterized by the sealing at the end of the feed pipe being provided as a double axial sealing. So it can be managed that one seal seals between the rotary feed pipe and the stationary supply pipe for the feed suspension and another seal seals between the headwall shaft of the rotor and the stationary part of the decanter centrifuge. This means that it will be possible to use the pressure from the feed pump to support the cake transport in the solids transporting part of the bowl, thereby eliminating the need for variable speed conveyor control and equipment.
Another embodiment of the invention is characterized by a liquid phase outlet for the clarified liquid being arranged between the bearing and the sealing.
Yet another favourable arrangement of the invention is characterized by the liquid phase valve being adjustable by a motor. The pressurization is created by this valve to the liquid phase discharge, thereby applying the pump pressure to support the cake transport in the solids part of the rotor in a controlled way.
A further advantageous embodiment of the invention is characterized by a channel for lubrication water being provided between the two seals and a bearing at the end of the rotating screw, which is arranged concentrically between the shaft of the rotating bowl and the shaft of the rotating screw.
Another favourable embodiment of the invention is characterized by the liquid phase conduit being arranged in the shaft of the rotating bowl. So it is incorporated in the main part and no separate part.
The invention is now described with reference to the accompanying drawings, wherein preferred embodiments of the invention are clearly shown.
In
In the hollow portion of the rotating bowl 1, a screw conveyor 2 is provided. The screw conveyor 2 is pivoted coaxially with the rotating horizontal axis of the bowl 1 with its shaft 30 supported by means of bearings 16 and 17. Bearing 16 is situated between the radially extending slotted portion of the conveyor shaft 30 that projects axially from the tube 12 at the feed end of the conveyor 2, and a radial projection from bowl shaft 8, into the slot. A hollow tube 12 of the screw conveyor 2 is provided coaxially at the centre of the rotating bowl 1. A screw blade 13 extends helically the full length of the hollow tube 12 so as to almost reach the inner surface of the bowl 1. In the hollow shaft 9 of the back end a transforming shaft 20 is provided. Its one end is connected to the end part of the hollow tube 12 of the screw conveyor 2 and its other end is connected to conveyor drive 22. Thus the bowl 1 with the screw conveyor 2 can be rotated with the high rotational speed. The rotating bowl 1 and the screw conveyor 2 are rotated in the same direction, while there is a slightly differential speed between them. This may be either accomplished by a gear unit or by different types of conveyor drives.
A solid discharge port 11 is formed at the smaller radius side of the rotating bowl 1 so that solidified particles scraped together can be discharged from the solids discharge port 11.
The portion, where the clarified liquid is discharged will be explained closely referring to
On the other side the clarified liquid, which collects on the outer surface of the hollow tube 12, flows to a channel 15 and enters a liquid phase conduit 4, which is formed in the shaft 8. This liquid phase conduit 4 extends trough the bowl-head 3 and the bearing stand 18 and opens into liquid phase outlet 5. While the liquid phase conduit 4 is rotating with the bowl 1, the liquid phase outlet 5 is stationary. The amount of liquid phase (clarified liquid) can be controlled with a liquid phase discharge valve 14. This liquid phase discharge valve 14 may be varied by a hand wheel 23 via a transmission or alternatively by a motor. By varying the liquid phase discharge valve 14 it will be possible to use the pressure from the feed pump (not shown) to support the cake transport in the solids transporting part of the bowl 1, thereby eliminating the need for variable speed conveyor control and equipment.
When the bowl 1 is rotating, liquid and solids fed into the bowl cavity will form a ring shaped volume, and solids having a higher density than the liquid will separate and accumulate on the inside of the bowl 1 forming a pool. If only liquid is supplied, the level of liquid inside the bowl will be constant and defined by the discharge port 11 having the largest radius from the rotational centre. A baffle disc 21 arranged on the conveyor will form a barrier between a separation part and a solids transport part of the bowl cavity, only leaving a small gap between the bowl wall and the baffle periphery. As the conveyor starts to transport separated solids towards the solids discharge port, this gap becomes filled with solids of a high viscosity, thereby forming a plug that causes the liquid level in the separation part of the bowl to become closer to the rotational centre, until it reaches the liquid discharge radius (which is smaller than the solids discharge radius). As the pressure at the gap is grossly proportional to the liquid level height, the pressure on the separation side of the baffle will become larger than the pressure on the transport side of the baffle and this pressure difference thereby aid the transport of solids through the gap and “up” to the solids discharge level. As the conduit between the feed pump and the bowl cavity is sealed, the pressure from the feed pump will add to the pressure in the cavity if the level inside the cavity comes closer to the rotational axis than the liquid discharge radius. The liquid phase discharge valve 14 will, when becoming partly closed, increase the pressure loss across the liquid discharge port and thereby increase the liquid discharge level, until it becomes coincident with the axis, and the bowl cavity is filled. When the cavity is filled, the pressure from the feed pump directly adds to the pressure at the baffle gap created by the centrifugal force, and the solids flow through the gap can therefore be controlled by regulation of the liquid phase valve gap.
As the solids transport can be controlled by the liquid phase discharge valve 14 as explained above, the dependency of the solids dryness of the conveyor speed is becoming less, and it will be possible to remove the control system for the conveyor speed and only have a fixed speed defined by the conveyor transmission ratio.
At the feed end, rotating feed pipe 10 is sealed by axial seal 6, while rotating bowl 1 is sealed by axial seal 7. Between axial seal 6 and axial seal 7 there is a space 24 into which cooling or lubrication water is introduced under pressure. This water flows through lubrication water channel 25 to the bearing 16 around screw shaft portion 30. Here also a portion of the clarified liquid may be used as lubrication water, so no fresh water is needed.
In
While preferred embodiments have been shown in the figures and described, it is apparent that the present invention is not limited to the specific embodiments thereof.
Number | Date | Country | Kind |
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14000941 | Mar 2014 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/054586 | 3/5/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/135823 | 9/17/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3428247 | Andresen | Feb 1969 | A |
4566873 | Toda | Jan 1986 | A |
5169377 | Schlip | Dec 1992 | A |
5171205 | Monkenbusch | Dec 1992 | A |
5217428 | Schlip | Jun 1993 | A |
5542903 | Nishida | Aug 1996 | A |
5618409 | Kreill | Apr 1997 | A |
9931643 | Huyghe | Apr 2018 | B2 |
20040185999 | Beyer | Sep 2004 | A1 |
20130190160 | Yumoto | Jul 2013 | A1 |
20170001202 | Michelsen | Jan 2017 | A1 |
Number | Date | Country |
---|---|---|
4132044 | Nov 1992 | DE |
2002336735 | Nov 2002 | JP |
Entry |
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Machine Translation of JP2002-336735 A. |
Number | Date | Country | |
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20170001202 A1 | Jan 2017 | US |