The present invention relates generally to a centrifugal separator for separation of particles from a gas stream.
WO 2010/090578 A1 discloses a centrifugal separator plant for separating oil in form of particles and/or mist from a fossil gas mixture for obtaining a separated gas. The plant comprises a centrifugal separator with a stationary casing defining a separation space. The centrifugal separator comprises an inlet for the gas mixture, a gas outlet for the separated gas and an oil outlet for discharging separated oil. A separating member for separating the gas mixture comprises a plurality of separating discs and is provided in the separation space. A drive motor is connected to the separating member via a spindle and rotates the separating member about an axis of rotation.
An object of the present invention is to increase the flexibility of a centrifugal separator for separation of particles from a gas stream, such as the type of centrifugal separator disclosed in the background art, in order to make it more suitable for use in existing vessel installations, such as pipelines for transporting gas. Another object is to provide a centrifugal separator for separation of particles from a gas stream which may be produced and installed at a reduced cost.
Thus the present invention relates to a centrifugal separator for separation of particles from a gas stream. Particles are defined as solid and/or liquid particles, such as oil droplets or oil mist. The centrifugal separator comprises a self-supporting frame for mounting inside an existing vessel for guiding the gas stream. The frame comprises a holding means to hold the frame at a position inside the vessel, and a first partition for dividing the vessel into a first section and a second section, wherein the first section is upstream of the second section. The centrifugal separator further comprises a gas inlet communicating with first section and a gas outlet communicating with second section. A centrifugal rotor is arranged to be rotatably supported in the frame around a rotational axis, the rotor having a first and a second end portion and comprising a plurality of separation plates, such as frustoconical separation discs or axial plates. The separation plates define separation passages between the plates, and the centrifugal separator is configured such that the first and second sections communicate via the separation passages of the rotor.
Furthermore, the present invention relates to a centrifugal separator for separation of particles from a gas stream, comprising a self-supporting frame for mounting inside an existing vessel for guiding the gas stream, the frame comprising a holding means to hold the frame at a position inside the vessel, and a first partition for dividing the vessel into a first section upstream of the partition and a second section downstream of the partition, a gas inlet communicating with the first section, a gas outlet communicating with the second section, a centrifugal rotor arranged to be rotatably supported in the frame around a rotational axis (x), the rotor having a first and a second end portion and comprising a plurality of separation plates defining separation passages between the plates, wherein the centrifugal separator is configured such that the first and second sections communicate via the separation passages of the rotor.
Thus the centrifugal separator may in a simple manner be fitted in existing vessel systems. The vessel may for example be a pressure vessel which may permit a pressure of at least 10 bars in the vessel such as a pipe or a pipeline for transporting gas. The vessel system does not need to be reconstructed or modified to allow for mounting the centrifugal separator, and thus the vessel system may be maintained and optimized to withstand high pressure and/or the installation cost may be reduced.
The frame may be sealingly connectable to the vessel, preferably in the region of the first partition, such that to sealingly divide the vessel into the first and a second sections. A seal may also be provided between the first partition and the centrifugal rotor. The seal may take the form of a narrow passage forming a gap sealing. Thus the gas stream is forced into the separation passages when flowing from the first section to the second section.
The frame may comprise a first frame portion, rotatably supporting the first end portion of the rotor in a first bearing, and a second frame portion, rotatably supporting the second end portion of the rotor in a second bearing. The first frame portion may comprise the first partition. Thus a more stable rotor construction may be achieved. Alternatively the frame may rotatably support the rotor in a single bearing in the first or second frame portion.
The frame may comprise a cylindrical tubular element connecting the first and the second frame portions, and wherein the centrifugal rotor is arranged inside the tubular element. Thus the frame may be constructed as a unit providing support to the first and second end portions of the rotor, which may be mounted within a vessel.
The frame may be provided with a general cylindrical shape, such as a circular cylindrical shape, to fit inside a cylindrical vessel, such as a circular cylindrical vessel.
The frame may be configured to be releasably connectable to a cylindrical inner surface of the vessel by means of the holding means. The centrifugal separator may further comprise a portion of the vessel for guiding the gas stream, wherein the portion of the vessel has a cylindrical inner surface and wherein the frame may be configured to be releasably connectable to a cylindrical inner surface of the vessel by means of the holding means. Thus the centrifugal separator may be mountable at various positions along the vessel, and may be removed from the vessel when needed, such as during maintenance.
The vessel may be configured to permit a pressure of at least 10 bars in the gas stream guided by the vessel. In such a vessel the centrifugal separator is particularly beneficial since the separator may be operated inside the vessel without any major modifications to the vessel, such as electrical or mechanical components or connectors led through the vessel wall.
The holding means may be configured to engage with the cylindrical inner surface of the vessel by providing an expandable outer diameter. Thereby the centrifugal separator may be mounted and releasably engaged with the cylindrical inner surface of the vessel in a simple manner. The holding means may be configured to sealingly engage with the cylindrical inner surface of the vessel.
The holding means may comprise one or more radially slotted frustoconical discs configured such that the outer diameter of the slotted disc may be expanded upon compression of the holding means. Thus the expandable outer diameter is realized by a device which may be operated by tightening compressive fastening means such as bolts. The slotted frustoconical discs may also have the effect to distribute the holding force around the circumference of the cylindrical inner surface of the vessel. Two or more radially slotted frustoconical discs may be arranged with the slotted portions mutually overlapping each other, thereby enabling the set of slotted frustoconical discs to sealingly engage with the cylindrical inner surface of the vessel.
The holding means may comprise an expandable element, such as a band formed as a circumferential component provided with a gap, which gap may be widened by a screw mechanism such that to provide the expandable outer diameter.
The holding means may comprise a spring element circumventing the frame and configured to engage with the cylindrical inner surface of the vessel by providing an elastically deformable outer circumference. The spring element may be a spiral spring extending along the outer circumference of the frame.
The vessel may comprise a flange, wherein the frame is configured to cooperate with the flange of the vessel, such that it is releasably connected to the flange of the vessel. Thus the centrifugal separator may be mountable to vessels provided with pipe flanges connecting two sections of the vessel. The centrifugal separator may also be mountable in a circumventing recess provided in the wall of a vessel, for example in connection with a pipe flange, whereby the holding means is configured to engage with the recess.
The holding means may be configured to support the centrifugal separator at a position inside the vessel, connecting it to any portion of the vessel.
The holding means may be arranged in the region of the first partition. Thus the centrifugal separator may be releasably fastened to or engaged with the vessel at a region adjacent to the first partition.
The centrifugal separator may further comprise a central gas chamber in the rotor communicating with a radially inner portion of the separation passages and the gas outlet, a space surrounding the rotor and communicating with a radially outer portion of the separation passages and the gas inlet. The separator may further comprise a device configured to bring the gas stream in rotation upstream of the rotor, and the centrifugal rotor may be configured such that the rotational flow of the gas mixture drives the rotation of the centrifugal rotor for separating particles from the gas stream being conducted from the space surrounding the rotor, through the separation passages between the plates and towards the central gas chamber. The centrifugal rotor may preferably be configured such that the rotational flow of the gas mixture alone drives the rotation of the centrifugal rotor for separating particles from the same gas stream.
Thus the centrifugal rotor may be brought into rotation by the rotational flow of the gas stream, whereby the centrifugal separator is not dependent on a separate drive motor to drive the rotor. Thereby the construction of the separator may be simplified, the cost may be decreased and the need for service and maintenance of the separator may be reduced. Since the rotor is driven in rotation by the rotational flow of the gas, the rotational speed of the rotor is similar to the rotational speed of the gas entering into the separation passages. This is particularly beneficial since it reduces the pressure drop over the separator. Further, since the rotating gas stream is led from the radially outer portions of the separation passages and towards the radially inner portions of the separation passages, the gas stream is spun up thanks to the conservation of angular momentum. Thus the transfer of the rotation from the gas to the rotor, such as by viscous forces, is particular efficient. Since the pressure drop over the centrifugal separator is limited, the holding force exerted by the holding means to hold the separator at a position in the vessel may be limited.
The invention further relates to a method wherein a centrifugal separator according to any one of the preceding claims is mounted in an existing vessel for guiding a gas stream such as an air duct, a duct for transporting gas or a pressure vessel such as a pipeline.
The gas stream may be a stream of fossil gas, natural gas, biogas, exhaust gas, ventilation gas, crankcase gas, carbon dioxide (CO2), hydrogen sulfide (H2S), etc.
The invention further relates to the use of a centrifugal separator as disclosed for separation of particles, such as solid or liquid particles from a stream of gas, such as a stream of fossil gas, natural gas, biogas, exhaust gas, ventilation gas, crankcase gas, carbon dioxide (CO2), hydrogen sulfide (H2S), etc, and/or applied to positions in gas compression, amine processes, Shell Claus off-gas treating (SCOT) processes, in exhaust gas scrubbing and the like. The invention further relates to the use of a centrifugal separator as disclosed for separation of particles, such as solid or liquid particles from a stream of gas in a pressure vessel, which vessel may be configured to permit a pressure of at least 10 bars in the gas stream guided by the vessel.
The invention is now described, by way of example, with reference to the accompanying drawings, in which:
In
The centrifugal separator further comprises a centrifugal rotor 5 arranged to be rotatable in the frame around a rotational axis x. The rotational axis extends in the direction of the extension of the vessel. The rotor comprises a shaft 26 having a first and a second end portion. The first end portion is supported in a first frame portion 15a by means of a first bearing 13. The first frame portion 15a comprises the first partition 15. The second end portion is supported in the frame by means of a second bearing 14 held in a second frame portion 21. With reference to
Again turning to
The frame comprises a bottom sealing ring 33 forming the gas inlet 3 in the frame. The bottom sealing ring is sealingly connected, 38, to the inner vessel wall 25. A cylindrical frame tube 24 extends along the inner wall of the vessel as a part of the frame, from the bottom sealing ring to the first partition 15 and connects with the other parts of the frame to provide a self-supporting frame structure. The second frame portion 21 supporting the second bearing 14 is connected to and supported by the inner wall of the cylindrical frame tube.
The frame 2 further comprises a holding means 20 to hold the frame at a position inside the vessel. The holding means comprises in a ring shaped part 34 sealingly connected, by means of a sealing member 37, to the inner vessel wall 25. The holding means is configured to engage with the cylindrical inner surface of the vessel by providing an expandable outer diameter. With reference to
Again with reference to
According to one embodiment, the vanes may be movable and/or the inclination of the vanes may be adjusted during operation in order to control the speed of rotation of the gas stream, and thus the rotation of the rotor.
In addition to, or as an alternative to what is shown in
With reference to
During operation of the centrifugal separator a stream of gas enters into the inlet 3 of the centrifugal separator 1. The stream of gas is forced into the passage 11 a where the inclined vanes 12 deflect the gas towards a tangential direction of the rotor of the separator. Thus the gas stream is brought into rotation by the vanes 12, and enters into the space 9 surrounding the rotor 5. In this space a pre-separation occurs whereas larger particles in the form of solid particles and/or liquid droplets having a density larger than the gas in the gas stream are separated from the gas stream by means of centrifugal forces in the rotating gas stream and deposited on the inner surface of the cylinder 24.
From the space 9 surrounding the rotor, the rotating gas stream enters into the separation passages 7 formed between the separation discs 6 in the rotor. The rotor 5 is brought into rotation by the rotating gas stream by means of viscous forces acting on the separation discs in the separation passages. The rotation of the rotor is also facilitated by the elongated distance members of the disc stack working as vanes or turbine blades to improve the transfer of momentum from the gas stream to the rotor. Since the rotating gas stream is led from the radially outer portions of the separation passages and towards the radially inner portions of the separation passages, the gas stream is spun up thanks to the conservation of angular momentum. Thus the transfer of the rotation from the gas to the rotor is particularly efficient in this configuration.
In the separation passages, particles in the form of solid particles and/or liquid droplets having a density larger than the gas in the gas stream are separated from the gas stream by centrifugal forces. Due to the smaller separation distances in the separation passages of the stack of frustoconical discs this even allows for separation of smaller and/or less dense particles from the gas stream. Particles separated from the gas stream are deposited on the inner surface of the frustoconical separation discs and transported radially outwardly by means of centrifugal forces. From the radially outer edge of the separation discs, particles separated from the gas stream in the separation passages are thrown towards and deposited at the inner surface of the cylinder 24.
Thus the rotational flow of the gas mixture alone drives the rotation of the centrifugal rotor, without a drive motor driving the rotor. The resulting rotation causes separation of particles from the same gas stream. Cleaned gas conducted towards the central gas chamber 8 of the rotor is provided to the outlet 4 through the passages 30 and 32 formed in the rotor and the first partition, and transported from the separator through the vessel.
Number | Date | Country | Kind |
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12194057.1 | Nov 2012 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/074147 | 11/19/2013 | WO | 00 |