WO2008116239A1 - Method and device for pumping gas-containing suspensions - Google Patents

Abstract

The invention relates to a method for pumping gas-containing suspensions, in particular fiber suspensions. The invention also relates to a device with a fluidizing rotor (5) having one or several impeller vanes (6) and a pump impeller (3), wherein the fluidizing rotor (5) projects into the suction intake (18) of the pump (1) and has a hub (17). By means of the special embodiment of the fluidizing rotor (5) and the arrangement thereof in the suction intake (18), sufficient pressure is generated to remove gas from the suspension without additional equipment in the assembly such as, for example, a vacuum pump.

Description

 Process and apparatus for pumping gaseous suspensions

The invention relates to a method for pumping gas-containing suspensions, in particular pulp suspensions, and to an apparatus for carrying out the method with a fluidizing rotor having one or more vanes and a pump impeller.

For pumping gaseous suspensions, a number of proposals are already known. For example, US Pat. No. 4,971,519 discloses a pump with a fluidizing rotor in the upper position, in which case the suspension is fluidized in such a way that it is substantially prevented that gas comes to the suction opening of the pump.

Furthermore, embodiments according to EP 0474 476 or EP 0474 478 are known in which behind the pump impeller, an impeller of a vacuum pump is arranged to suck the gas. In all these variants, as well as in EP 1 147 316, a zone is generated by the rotation in the center of the rotor, in which the gas is deposited. The gas to be separated is generally air, but may be another gas in specific applications. All versions have the disadvantage that for discharging the gas, an additional device either directly in the pump or separately, is needed. For other applications, e.g. Pumping and separating two-phase liquids, especially oil suspensions, are already available according to the

US 4 886 530 pumps with special rotors having wound wings on a shaft. A separate Fluidisierungsrotor, as it is provided for pulp suspensions, is not present here. Furthermore, EP 330 387 A2 describes a process for the degassing of suspensions, in which the impeller generates a separation of suspension and gas, wherein the gas in the

Center of the impeller accumulates. The suspension is fed to the impeller by a rotating conveyor. This device has no fluidization rotor. EP 298 693 A2 describes a device in which the gas collects on the shaft, sucked through slots in this shaft and then fed back through slots of the suspension and is discharged together with this from the pump. WO 2000/43677 A1 shows a device in which the zone of lower pressure at the foot of the wing, in particular in the vicinity of the axis, is located on the impeller. Thus, it can not be sufficiently separated gas. The present invention seeks to remedy the above drawbacks save an additional unit.

The invention is therefore characterized in that zones of low pressure and zones of higher pressure are generated on a fluidizing rotor with one or more wings on the wings, which lower the gas at the zones

Pressure is separated from the suspension and conveyed by means of the fluidizing rotor, in particular in the suction nozzle of the pump, generated pressure to the pump impeller, wherein the fluidizing rotor, in particular in the suction nozzle of the pump, generates a pressure which discharges the gas without suction from the pump , A special design of the pump with integrated vacuum pump or a separate vacuum pump can be dispensed with.

An advantageous development of the invention is characterized in that the gas is passed through openings in the pump impeller in a separation chamber.

It has proven particularly favorable if the flow rate of the suspension in the suction nozzle of the pump is between 0.5 m / s and 4.0 m / s, preferably between 1.0 m / s and 3.0 m / s, for example less than 3 m / s is. Thus, the gas can be effectively separated without being entrained by the suspension in the pump impeller.

The invention also relates to a device for pumping gaseous suspensions, in particular pulp suspensions, with a fluidizing rotor having one or more vanes and a pump impeller, the fluidizing rotor protruding into the suction nozzle of the pump and having a hub. It is characterized in that the ratio of suction nozzle diameter to free length of the fluidizing rotor satisfies the following equation: Ds / FL> 0.0024 * Dp + 0.7 where D ₃ the suction nozzle diameter FL the free length of the fluidizing rotor (total length - length of the hub)

D _p denotes the pressure nozzle diameter.

The device is also characterized in that the aspect ratio λ satisfies the following equation: λ <-0.0055 * Dp + 2.15 for D _p <250 mm and λ <0.775 for Dp> 250 mm where the aspect ratio λ is defined as the free length FL of the fluidizing rotor (total length - length of the hub) / blade width b / Number of wings n and D _p denotes the pressure nozzle diameter.

It has proven to be particularly favorable if the rotor length L _sp in the suction nozzle is greater than 0.5 suction nozzle diameter D _s , preferably greater than 0.6 suction nozzle diameter D _s . A particularly good variant of the invention is characterized in that the ratio of the length of the hub of the fluidizing rotor to the length of the suction nozzle is between 0.9 and 1.1, preferably about 1.0, and the wings of the fluidizing rotor extend as far as the pump impeller. As a result, zones of lower or higher pressure can form on the upper or lower side of the vanes (viewed in the direction of rotation of the impeller), at which the gas can be deposited, and the separated gas is prevented from collecting in the center, so that the generated pressure can carry the gas out of the system without additional aids. In the region of the suction nozzle, the fluidizing rotor generates a high pressure on the part facing the pump impeller, through which the gas can be removed without further units.

A favorable embodiment of the invention is characterized in that the wings are band-shaped and the curvature of the surface of the wing decreases from the free end in the direction of the pump impeller, wherein this can be done continuously, for example linear. By this shape of the wings on the pump impeller facing part, in particular in the suction nozzle a high

Pressure generated by which the gas can be removed without further aggregates.

If the surface of the wings at the entrance end is arranged nearly perpendicular to the axis, the entry losses can be greatly reduced. It has proven advantageous if the surface of the wing merges at the outlet end at a shallow angle to the axis in the wings of the pump impeller. This achieves a smooth transition from the fluidizing rotor to the pump rotor and reduces the deflection losses. If the pump impeller has further vanes for conveying the degassed pulp suspension, which are arranged between the vanes connected to the fluidizing rotor, a better delivery of the suspension can be achieved. With openings provided in the pump impeller on the negative pressure side of the vanes, which openings may communicate with a separation space, the vapor deposition can be made even more effective. Advantageously, it has been found that the fluidizing rotor has four blades. Thus, a good power distribution can be achieved. When the fluidizing rotor is free at the entrance end in the center, the

Suspension flow freely in the direction of the pump impeller, whereby the efficiency of the device is still increased.

The invention will now be described by way of example with reference to the drawings, in which Fig. 1 is a 3D view of a fluidization rotor and impeller according to the invention

Fig. 2, a longitudinal section through a device according to the invention, Fig. 3 is a plan view of the Fluidisierungsrotor.

Fig. 1 shows the pump 1 according to the invention, which consists of a housing 2, a pump impeller 3 with wings 4 and a fluidizing rotor 5 with wings 6. Advantageously, four wings 6 are used. The wings 6 are band-shaped and the curvature of the surface of the wings 6 decreases from the free end 7 in the direction of the pump impeller 3 from. At the free entry end 7, the surface of the wings 6 is aligned almost perpendicular to the axis. This minimizes entry loss and allows greater force to be transferred to the suspension. The surfaces of the wings 6 at the outlet end 8 are arranged at a shallow angle to the axis and go into the wings 4 of the pump impeller 3 over. Furthermore, 4 more wings 9 are provided between the wings, which increase the flow rate of the pump 1. The base plate 10 of the pump impeller 3 has a number of

Openings 11 which are arranged on the negative pressure side of the wings 4 and 9 and serve for the removal of the collected gas. When the fluidizing rotor 5 rotates in the direction 13, negative pressure zones are formed in the direction of rotation on the impeller, at the top of the vanes 6. Due to the shape of these wings according to the invention, the gas which has precipitated there is pressed in the direction of the pump impeller 3 and separated there from the delivery flow through the openings 11. Furthermore, a sufficient pressure is generated by the wings 6, to dissipate the separated gas and thus it can be saved a subsequent vacuum pump. Due to the relatively large width b of the wing 6 in relation to the diameter dN of the hub 17, which corresponds approximately to the free space in the center, the deposition of the gas, especially the air, on the wings 6 can be strongly supported. This also makes it easier to convey the suspension in the center. Also, the wings 6 can thereby exert a greater delivery pressure on the suspension and also the separated gas.

The choice of the diameter D _{s of} the suction nozzle should be such that at a given throughput, a flow rate in the suction nozzle between 0.5 m / s and 4 m / s, preferably between 1, 0 m / s and 3.0 m / s results , This flow rate, especially below 3 m / s leads to an optimal

Separation of the gas from the suspension.

Fig. 2 shows a longitudinal section through the device according to the invention, wherein like parts are designated by the same reference numerals. One recognizes here well the wings 6 of the fluidizing rotor 5 as well as the wings 4 and the shorter wings 9 of the pump impeller 3. At the back of the pump impeller 3 is a separation chamber 12 in which the deposited on the wings 6 from the suspension and by the Fluidizing rotor 5 is deposited through the openings 11 pressed gas, passed into a Gasabscheidekammer 20 and then discharged via a line 16. On the back of the impeller 3 and 15 wings can still be arranged, the one

Allow separation of entrained fibers from the gas stream. The degassed suspension is then conveyed through the outlet 14. It can be clearly seen here that the length IN of the hub 17 of the fluidizing rotor 5 is substantially the length L of the suction nozzle 18 of the pump 1. In the range of the ratio IN / L between 0.9 and 1.1, the best values for the gas separation and the pump efficiency are achieved. Furthermore, the best results have resulted in a ratio of diameter d of the fluidizing rotor 5 to diameter D of the pump impeller 3 of greater than 0.5. FIG. 3 shows a plan view of the fluidizing rotor 5 in the direction of the pump impeller 3. It can be seen that the wings 6 strongly overlap and that in the center remains a free space 19 which is filled with suspension. Due to the relatively wide running wings 6, this inner space 19 is kept as low as possible. Due to the relatively large width b of the wing 6 in relation to the diameter dN of the hub 17, which corresponds approximately to the free space in the center, the deposition of the gas, especially the air, on the wings 6 can be strongly supported. This also makes it easier to convey the suspension in the center. Also, the wings 6 can thereby exert a greater delivery pressure on the suspension and also the separated gas. The free (not connected) entrance ends 7 are clearly visible here. Furthermore, the ratio of the diameter d / D of the fluidization rotor 5 and the impeller 3 can be seen. Also, the hub 17 and the suction port 18 can be seen here. As a result of the rotation of the fluidizing rotor 5 in the direction of the arrow 13, a higher pressure is produced on the underside of the wing 6 in the direction of the impeller 3. At the same time results on the top of the wings 6, a zone of lower pressure. Due to the design of the wings 6 and the slope, the suspension is conveyed to the impeller 3. The hub 17 prevents the escape of the gas in the center 19 whereby the gas is guided along the underside of the wings 6 and is discharged through the openings 1 1 in the base plate 10 of the impeller 3 in the Gassammeiraum. By substantially the same length I _N of hub 17 and length L of the suction nozzle 18, a further pressure build-up is made possible in this area, whereby the gas can be discharged through the line 16 without further aggregate subsequently.

EXAMPLES

A pump in the prior art has a suction nozzle diameter of D ₃ = 200 mm, a pressure nozzle diameter D _p = 150 mm, a blade width of b = 45mm, 3 blades and a free length of the fluidizing rotor of FL = 305 mm.

This results on the one hand in a λ = 2.26, which is much larger than 1. 325, and the ratio Dg / FL of 0.66, which is much smaller than 1.06. It has been shown that an additional vacuum pump is absolutely necessary here for pumping gas-containing suspensions, in order to ensure sufficient separation of the gas and thus also adequate delivery of the suspension. In experiments, a pump with suction nozzle diameter of

D ₈ = 175 mm, a pressure nozzle diameter D _p = 100 mm, a blade width of b = 50 mm, 4 blades and a free length of the fluidization rotor of FL = 160 mm used. On the one hand, this results in a λ = 0.8, which is substantially smaller than 1.57, and the ratio Ds / FL of 1.10, which is substantially greater than 1. 03.

In an embodiment according to these values, a very good separation of the air resulted from a pulp suspension, which also significantly improved the efficiency of the pump and led to a lower energy consumption. In particular, a subsequent vacuum pump could be omitted.

Pumps were used for larger throughputs with suction nozzle diameters of D ₈ = 400 mm or 475, pressure nozzle diameter D _p = 250 mm or 300 mm, blade widths of b = 110 mm or 120 mm, 4 blades and a free length of the FL fluidizing rotor = 240 mm or 270 mm. On the one hand this results in a λ = 0.55 or 0.56, which is considerably smaller than 0.775 or is below this limit value of 0.775, and the ratio Ds / FL of 1.67 or 1.76, which is essential greater than 1, 3 and 1, 39, respectively. For larger pumps with pressure nozzle diameters greater than 250 mm, it has been shown that the geometry of the fluidizing rotor changes only insignificantly with constant power.

Again, a subsequent vacuum pump can be omitted, resulting in large

Energy savings but also leads to savings in investment costs.

Due to the relatively wide and relatively long and far reaching into the standpipe wing of the fluidizing rotor is very good, the gas from the

Suspension separated and discharged by the pressure generated.

The invention is not limited by the examples. It can also be selected, for example, other dimensions that are highly dependent on the size and the Delivery of the pump are. Essential, however, are the basic design of the fluidizing rotor and the arrangement in the pump housing / suction nozzle, whereby the fluidizing rotor presses the separated gas out of the pump and no additional facilities for vacuum generation are more necessary.

Claims

claims 1. A method for pumping gaseous suspensions, in particular pulp suspensions, characterized in that seen at a fluidizing rotor with one or more wings in the direction of rotation on the impeller at the top of the wing zones of low pressure and at the bottom of the wing zones of higher pressure be that the gas is deposited at the zones of low pressure from the suspension and conveyed by means of the pressure generated by the fluidizing rotor, in particular in the suction nozzle of the pump to the pump impeller. 2. The method according to claim 1, characterized in that the fluidizing rotor generates a pressure which discharges the gas without suction from the pump. 3. The method according to claim 1 or 2, characterized in that the flow rate of the suspension in the suction nozzle between 0.5 m / s and 4.0 m / s, preferably between 1, 0 m / s and 3.0 m / s, For example, less than 3 m / s. 4. The method according to any one of claims 1 to 3, characterized in that the gas is passed through openings in the pump impeller in a separation chamber. 5. An apparatus for pumping gaseous suspensions, in particular pulp suspensions, with a fluidizing rotor having one or more vanes and a pump impeller and a discharge nozzle, wherein the fluidizing rotor projects into the suction nozzle of the pump and has a hub, characterized in that the ratio of suction nozzle diameter ( D _s ) to free length (FL) of the fluidization rotor satisfies the following equation: Ds / FL> 0.0024 ^* D _p + 0.7 where Ds is the suction nozzle diameter FL the free length of the fluidizing rotor (total length - length of the hub) Dp denotes the pressure nozzle diameter. 6. An apparatus for pumping gaseous suspensions, in particular pulp suspensions, with a fluidizing rotor with one or more vanes and a pump impeller and a discharge nozzle, wherein the fluidizing rotor projects into the suction nozzle of the pump and having a hub, characterized in that the aspect ratio λ following equation is sufficient: λ <-0.0055 * Dp + 2.15 for D _p <250 mm and λ <0.775 for D _p > 250 mm wherein the aspect ratio λ is defined as the free length (FL) of the fluidization rotor (total length - length of the hub ) / Wing width (b) / number of wings (n) and D _p denotes the pressure nozzle diameter 7. Apparatus according to claim 5 or 6, characterized in that the rotor length (L _sp ) in the suction nozzle is greater than 0.5 Saugstutzendurchmesser (D _s ), preferably greater than 0.6 Saugstutzendurchmesser (D _s ). 8. The device according to claim 5, characterized in that the ratio of the length (I _N ) of the hub (17) of the fluidization rotor (5) to the length (L) of the Suction nozzle (18) between 0.9 and 1, 1, preferably about 1, 0 and the wings (6) of the fluidization rotor (5) to the pump impeller (3) extend. 9. Device according to one of claims 5 to 8, characterized in that the wings (6) are strip-shaped and the curvature of the surface of the wings (6) decreases from the inlet end (7) in the direction of the pump impeller (3). 10.Vorrichtung according to claim 9, characterized in that the curvature of the surface of the wings (6) from the inlet end (7) in the direction of the impeller (3) decreases continuously. 11. The device according to claim 10, characterized in that the curvature of the surface of the wings (6) decreases linearly from the inlet end (7) in the direction of the pump impeller (3). 12. Device according to one of claims 5 to 11, characterized in that the surface of the wings (6) at the inlet end (7) is arranged almost perpendicular to the axis. 13. Device according to one of claims 5 to 12, characterized in that the surface of the wings (6) at the outlet end (8) in a flat Angle to the axis in the wings (4) of the pump impeller (3) passes. 14. The apparatus according to claim 13, characterized in that the pump impeller (3) further wings (9) for conveying the degassed pulp suspension, which are arranged between the wings (6) connected to the at the fluidization rotor (5) wings , 15. Device according to one of claims 5 to 14, characterized in that in the pump impeller (3) on the negative pressure side of the wings (4) openings (11) are provided. 16. The apparatus according to claim 15, characterized in that the openings (11) with a separation chamber (12) are in communication. 17. Device according to one of claims 5 to 16, characterized in that the fluidizing rotor (5) has four wings (6). 18. Device according to one of claims 5 to 17, characterized in that the fluidizing rotor (5) is free at the inlet end (7) in the center.