RU2530979C2 - Device for pumping gas suspensions, in particular fibrous suspensions - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention is related to device for pumping gas suspensions, in particular fibrous suspensions. The device comprises fluidising rotor (2) with one or more vanes (5), pump impeller and pressure tube (7). The fluidising rotor (2) is located in the pressure tube (6) of the pump (1) and has a hub (3). The centre of the fluidising rotor (2) input end (4) is made hollow and the vanes (5) are operated freely without synergy or mutual coupling. The ratio of the fluidising rotor (2) free length (F_I) to the fluidising rotor diameter (Dr) is from 0% up to 75%.

EFFECT: invention may ensure the required stability for all application areas.

10 cl, 3 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a device for pumping gas-containing suspensions, in particular fibrous suspensions, including a fluidizing rotor with one or more vanes, a pump impeller and a pressure pipe, the fluidizing rotor being placed in the pump suction pipe and having a hub, the center of the inlet end of the fluidizing rotor is hollow , and the blades work freely, without mutual reinforcement or mutual connection.

State of the art

A number of devices for pumping gas-containing suspensions are known. Thus, US Pat. No. 4,971,519 (Timperi) discloses a pump with a front-mounted fluidizing rotor, the suspension being fluidized in such a way that gas is generally prevented from entering the suction port of the pump. Further, device designs are known according to EP 0474476 and EP 0474478, in which an impeller of a vacuum pump for suctioning gas is located behind the impeller of the pump. In all these variants, as in the embodiment according to EP 1147316, due to rotation in the center of the rotor, a zone is created in which gas is released. The gas to be released is, in general, air, but in special applications it can be another gas. All these designs have the disadvantage that an additional device is required for gas removal, located either directly in the pump or separately from it. Further, DE 69924021T2 discloses a fluidizing rotor with a cavity in the center, i.e. without a central shaft. WO 2000/34663 also presents a centrifugal pump. There are additional vanes here, at least on some of the impeller vanes. However, a separate fluidizing rotor is not provided.

US Pat. No. 5,039,320 and US Pat. No. 5,615,997 disclose fluidizing rotors in which the reinforcing vanes are connected at the outer edge and, in addition, there is a bearing sleeve. The cross section here is greatly narrowed, which can very easily lead to clogging of the fibers. In documents US 4637779 and US 5087171 presented devices with mounted rotors that do not reach the suction pipe, while the hub reaches the end of the suction pipe. Because of this, it is impossible to either divert gas or to suck out the pump without additional devices.

The present invention eliminates the above disadvantages, which eliminates the need for an additional device while maintaining the stability of the fluidizing rotor.

Disclosure of invention

Thus, the present invention is characterized in that the ratio of the free length F _I (i.e., the length without a hub) of the fluidizing rotor to the diameter Dr of the fluidizing rotor is from 0% to 75%, preferably from 10% to 20%. This achieves good stability and, at the same time, high efficiency.

One of the preferred further developments of the present invention is characterized in that the fluidizing rotor extends beyond the suction port of the pump. Due to this, the suspension intended for pumping is easier to supply to the suction pipe.

One of the successful embodiments of the present invention is characterized in that the fluidizing rotor has wide blades, whereby more than 40% overlap of the cross section of the suction pipe is achieved, preferably more than 60%.

By arranging the surfaces of the blades at the inlet end substantially perpendicular to the axis, input losses can be significantly reduced.

Preferably, as it turned out, equip the rotor with four blades. In this case, a good distribution of forces can be achieved.

The invention also relates to a pump rotor for pumping gas-containing suspensions, in particular fiber suspensions, characterized in that the ratio of the free length F _{I of the} fluidizing rotor to the diameter Dr of the fluidizing rotor is from 0% to 75%, preferably from 10% to 20%.

Particularly successful was an embodiment in which the fluidizing rotor has wide blades.

By arranging the surfaces of the blades at the inlet end substantially perpendicular to the axis, input losses can be significantly reduced.

Preferably, as it turned out, equip the rotor with four blades. In this case, a good distribution of forces can be achieved.

A brief description of the graphic materials

Below the present invention is described by way of example with reference to the drawings, in which are presented:

figure 1 - three-dimensional image of the fluidizing rotor according to the invention and the impeller of the pump,

figure 2 is a view of the device according to the present invention,

figure 3 is a top view of the fluidizing rotor.

The implementation of the invention

Figure 1 shows a pump 1 with a fluidizing rotor 2 having a hub 3. The surfaces of the blades 5 at the inlet end 4 are perpendicular to the axis of the fluidizing rotor 2. This minimizes the hydraulic input losses, thereby increasing the efficiency of the pump. The fluidizing rotor 2 is placed in the suction nozzle 6 of the pump 1, while the fluidized suspension, in particular the fiber suspension, is driven by the impeller to the pressure nozzle 7. The fluidizing rotor 2 protrudes from the suction nozzle 6, for example, into the container from which the suspension is to be pumped, due to which can be facilitated by the flow of the suspension to the suction pipe 6. The hub 3 of the fluidizing rotor 2 is attached to the pump shaft 9 with a screw 8.

FIG. 2 shows a pump 1 with a fluidizing rotor 2 according to the invention. It is especially clearly seen here that the center of the inlet end 4 of the fluidizing rotor 2 is hollow, and the blades 5 work freely, without mutual reinforcement or mutual connection. This hollow end has a free length F _I from the edge to the hub 3. As it turned out, it is particularly preferable when the ratio of the free length F _{I of the} fluidizing rotor to the diameter Dr of the fluidizing rotor is in the range from 0% to 75%, preferably about 40%. It turned out that in this embodiment, the fluidizing rotor 2 is very stable and can be used in almost all conditions of use.

FIG. 3 shows a fluidizing rotor 2 according to the invention; four blades 5 are very clearly visible, which converge to the centrally located hub 3 and in the course of operation drive the suspension, in particular the fibrous suspension, to the discharge pipe 7. The blades 5 have at the same time strength providing adequate stability.

The selected embodiment, first of all, provides for the separation on the blades and the removal of gas from gas-containing suspensions, in particular fibrous suspensions, so that you can do without the expensive and increasing costs of a vacuum pump.

The present invention is not limited to the examples given. So, for example, other sizes can be selected, which depend on the size and performance of the pump. However, the fundamental design of the fluidizing rotor and its placement in the pump housing / suction nozzle are essential, due to which the fluidizing rotor squeezes the released gas from the pump, and any additional devices for creating a vacuum are no longer required.

Claims (10)

1. Device for pumping gas-containing suspensions, in particular fibrous suspensions, including a fluidizing rotor (2) with one or more blades (5), a pump impeller and a pressure pipe (7), the fluidizing rotor (2) being placed in the suction pipe (6) ) of the pump (1) and has a hub (3), the center of the inlet end (4) of the fluidizing rotor (2) is hollow, and the blades (5) work freely, without mutual reinforcement or mutual connection, characterized in that the ratio of the free length (F _I) fluidizing rotor (2) to the diameter (Dr) psevdoozh zhayuschego rotor is from 0% to 75%. 2. The device according to claim 1, characterized in that the ratio of the free length (F _I ) of the fluidizing rotor (2) to the diameter (Dr) of the fluidizing rotor is from 10% to 20%. 3. The device according to claim 1 or 2, characterized in that the fluidizing rotor (2) protrudes beyond the suction pipe (6) of the pump (1). 4. The device according to claim 1 or 2, characterized in that the fluidizing rotor (2) has wide blades (5), providing an overlap of more than 40% of the cross section of the suction pipe, preferably more than 60%. 5. The device according to claim 1 or 2, characterized in that the surfaces of the blades (5) at the inlet end (4) are located essentially perpendicular to the axis. 6. The device according to claim 1 or 2, characterized in that the fluidizing rotor (2) has four blades (5). 7. A pump rotor for pumping gas-containing suspensions, in particular fibrous suspensions, the center of the inlet end (4) of the fluidizing rotor (2) being hollow and the blades (5) working freely, without mutual reinforcement or mutual coupling, characterized in that the ratio is free the length (F _I ) of the fluidizing rotor (2) to the diameter (Dr) of the fluidizing rotor is from 0% to 75%. 8. The rotor according to claim 7, characterized in that the ratio of the free length (F _I ) of the fluidizing rotor (2) to the diameter (Dr) of the fluidizing rotor is from 10% to 20%. 9. The rotor according to claim 7 or 8, characterized in that the surfaces of the blades (5) at the inlet end (4) are located essentially perpendicular to the axis. 10. The rotor according to claim 7 or 8, characterized in that the fluidizing rotor (2) has four blades (5).

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