RU2488025C1 - Beet lifting pump - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: beet lifting pump comprises casing with pipes and impeller fitted in cantilever on the shaft. Coatings from resilient material is fitted on casing inner surface and surfaces of impeller. Impeller bent vane is made of composite material including tuber-fabric shell and collapsible carcass. The latter includes main part and tail part representing a stiff and a flexible components, respectively. Curvilinear grooves are made of said tail part rubber-fabric shell surface coated with resilient material. Impeller shaft is equipped with drive furnished with rpm controller connected with pressure controller connected, in its turn, with pressure gage arranged in pressure branch pipe. Pressure controller incorporates interconnected comparator and setting device, electronic and magnetic amplifiers, and nonlinear feedback unit. RPM controller is composed of the unit of powder electromagnetic couplings.

EFFECT: reduced power consumption thanks to maintenance of normalised drag in pressure branch pipe and elimination of dirt sticking.

3 dwg

Description

The invention relates to a pump engineering and can be used in the sugar industry for raising and feeding beets to the washing department of a sugar factory.

Known beetroot pump (see RF patent No. 2200878 IPC F04D 7/04, 29/24. Publ. March 20, 2003), comprising a housing with suction and discharge nozzles and an impeller cantilevered on the shaft, consisting of a front and rear disks in the form of cones and curved blades fixed between them, while on the inner surface of the casing and the surface of the impeller are placed coatings of elastic material, while the curved blade of the impeller is made of composite material, which includes a rubber-fabric shell and a prefabricated frame containing the main section, representing a rigid structure and a shank, representing a flexible structure, and the rubber-fabric shell is evenly distributed over the entire volume of the prefabricated frame, and curvilinear grooves converging to the exit of the curved blade are made on the shank along the surface of the rubber-fabric shell coated with elastic material.

The disadvantages of this design are increased energy consumption during long-term operation, due to the need to overcome the increasing hydraulic resistance of the discharge pipe due to the accumulation of contaminants on its inner surface, accompanying the supply of beets with heavy and light impurities.

Known beetroot pump (see RF patent No. 2416741 IPC F04D 7/04 / Pub. 04/20/2011. Bull. No. 11), comprising a housing with suction and discharge nozzles and an impeller cantilever mounted on the shaft, consisting of a front and rear disks in the form the cones and the curved blades fixed between them, on the inner surface of the casing and the surfaces of the impeller are placed coatings of elastic material, while the curved impeller blade is made of composite material, which includes a rubber-fabric shell and a prefabricated frame containing the main section, representing a rigid structure and a shank, representing a flexible structure, and the rubber-fabric shell is evenly distributed throughout the entire volume of the prefabricated frame, and on the shank along the surface of the rubber-fabric shell coated with elastic material, curved grooves are made, converging to the exit of the curved blade, while curved grooves are made on the inner surface of the discharge pipe, the tangent of which has a clockwise direction, and the tangent of curved the wave on the shank along the surface of the rubber-fabric sheath has a counterclockwise direction

The disadvantage is the excessive energy consumption of rotation of the shaft with the impeller, set as calculated at the maximum pressure in the discharge pipe according to the condition of the normalized hydraulic resistance of the water flow, transported from above mainly with heavy impurities.

The objective of the invention is to regulate the energy consumed by rotation of the shaft with the impeller, depending on the pressure in the discharge pipe, determined by the hydraulic resistance of the water flow during transportation during operation of both heavy small and mainly light impurities.

The technical result of reducing energy consumption during operation is achieved by the fact that in a beet pump containing a housing with suction and discharge nozzles and an impeller cantilever mounted on the shaft, consisting of a front and rear disks in the form of cones and curved blades mounted between them, on the inner surface of the housing and the surfaces of the impeller are coated with elastic material, while the curved impeller blade is made of composite material, which includes rubber fabric a shell and a prefabricated frame containing a main portion representing a rigid structure and a shank representing a flexible structure, and a rubber-fabric shell is uniformly distributed throughout the volume of the prefabricated frame, and curved grooves are made on the shank over the surface of the rubber-fabric shell coated with elastic material, converging to the exit curved blades, while on the inner surface of the discharge pipe made curved grooves, the tangent of which has a direction along the clock Christmas trees, and the tangent of the curved grooves on the shank along the surface of the rubber-fabric sheath has a counterclockwise direction, according to the invention, the impeller shaft is equipped with a drive with a speed controller, and the speed controller is connected to a pressure controller connected to a pressure sensor located in the discharge pipe, the pressure regulator contains interconnected blocks of comparison and reference, electronic and magnetic amplifiers and a nonlinear feedback block, in addition, it is regulated the rotational speed is in a block of electromagnetic powder clutches.

Figure 1 schematically shows a beet pump with a drive and an automated pressure control system; figure 2 - the shank of the curved impeller blades with curved grooves, the tangent of which has a counterclockwise direction; figure 3 the inner surface of the discharge pipe with curved grooves, the tangent of which has a direction in the clockwise direction.

The beet pump contains a cylindrical housing 1, along the horizontal axis of which there is a suction pipe 2, and a discharge pipe 3 is installed along a tangent to the housing. Inside the housing 1, an impeller consisting of a front disk 6, a rear disk is mounted cantilever on a shaft 4, mounted in a support 5 7 and curved blades 8. The blade 8 is made of composite material, which includes a rubber-fabric shell 9 and a prefabricated frame containing a main section 10, representing a rigid structure, and a shank 11, representing bending structure, the shank 11 of the shell 9 rubber-coated elastic material 12, the grooves 13 are made curvilinear, converging to the exit curved vanes 8. The rear disc 7 is in the form of a cone, while the front disc 6 - in the form of a truncated cone.

The rear disk 7 with the top of its case faces the nozzle 2, and the front disk 6 with its large base faces the rear disk 7. The disks 6 and 7 are rigidly interconnected by curved blades 8. On the inner surface of the housing 1, the surface of the rear disk 7, the front disk 6 placed cover 12 of an elastic material, for example, polyethylene. On the inner surface 14 of the discharge pipe 3, curved grooves 15 are made, the tangent of which has a clockwise direction, and the tangent of curved grooves 13 on the shank 11 along the surface of the rubber-fabric shell 9 coated with material 12 has a counterclockwise direction.

Beet pump works as follows.

The shaft 4 by means of a speed controller 16 is connected to the drive 17. The speed controller 16 is connected to a pressure controller 18 connected to a pressure sensor 19 located in the discharge pipe 3. Moreover, the pressure controller 18 contains a comparison unit 20 and a task unit 21, and the block comparison 20 is connected to the input of an electronic amplifier 22, equipped with a nonlinear feedback unit 23, and the output of the electronic amplifier 22 is connected to the input of a magnetic amplifier 23 with a rectifier connected to an output speed controller 16 in the form of a block of powder electromagnetic couplings of the drive 17 of the beet pump.

The drive power 17 for rotating the impeller shaft 4 is selected nominal for the case of maximum pressure in the discharge pipe 3, which is detected by the pressure sensor 19 of the water flow transporting the beets. However, during the operation of the beet pump in the water stream, along with the beets and heavy impurities, significant quantities of light impurities appear that require less effort when transporting with beets, while the power of the drive 17 remains constant, i.e. there is an unreasonable waste of energy. The proposed technical solution controls the speed of rotation of the shaft 4 of the impeller, which allows to optimize the energy consumption of the drive 17 by reducing them depending on the ratio in the water flow transporting beets of heavy and light impurities. So, when a significant amount of light impurities appears in the water stream, the force required to transport the beets decreases, with a decrease in pressure in the discharge pipe 3, which is detected by the pressure sensor 19 and the signal coming from it to the pressure regulator 18 becomes larger than the signal block 21 and the output of the comparison block 20 will receive a signal of negative polarity, which is fed to the input of the electronic amplifier 22, simultaneously with the signal of negative nonlinear communication of block 23. Due to this, in the electronic ilitele 22 offset the nonlinearity characteristics of the drive 17 sveklonasosa. The signal from the output of the electronic amplifier 22 is fed to the input of the magnetic amplifier 23, where it is amplified by power, rectified and fed to the speed controller 16 in the form of a block of powder electromagnetic couplings. The negative polarity of the signal of the electronic amplifier 22 causes a decrease in the excitation current at the output of the magnetic amplifier 23. As a result, the power taken from the drive 17 is reduced, i.e. energy is saved when the beets are transported in a normalized way by the water flow. An increase in the heavy impurities in the water flow transporting beets leads to an increase in efforts to move the beets with an increased amount of heavy impurities, and the pressure in the discharge pipe 3 increases, which is detected by the pressure sensor 19 and the signal from the pressure regulator 18 becomes smaller than the signal of the reference unit 21, and at the output of the comparison unit 20, a signal of positive polarity appears, which is fed to the input of the electronic amplifier 22, simultaneously with the signal of the negative nonlinear feedback from ides block 23. The output of the electronic amplifier 22 is input to the magnetic amplifier 23, which amplifies power is rectified and supplied to the speed controller 16 as a block of electromagnetic powder clutches. The positive polarity of the signal of the electronic amplifier 22 causes an increase in the excitation current at the output of the magnetic amplifier 23. As a result, the selected power increases, approaching the nominal for the case of maximum pressure in the discharge pipe 3, therefore, the beet pump, operating in the mode of smooth change of power on the drive 17 by means of a speed controller rotation 16 under the condition of different quantitative influx of heavy and light impurities in the water flow transporting beets, provides savings nergii.

For each of the operating modes of the beet pump (the predominant presence of heavy and light impurities, as well as any of their ratios) in housing 1, the following is carried out. The water flow transporting beets with heavy and light impurities when moving along curved grooves 13 of the shank 11 swirls counterclockwise and breaks away from the surface of the rubber-fabric shell, and when it enters the discharge pipe 3, this flow begins to move along curved grooves 15 located on the inner surface 14, and twists clockwise. Moreover, in the zone of separation of the water flow from the shank 9 and the subsequent entrance to the discharge pipe 3, microvortices of heavy and light impurities with mutually opposite directions of rotation are formed, the contact of which leads to microexplosions that impede the process of adhesion of contaminants on the inner surface 14 of the discharge pipe 3. As a result, the operation of the beet pump, the flow area of the discharge pipe 3 does not decrease due to the accumulation of contaminants on the inner surface 14, i.e. the hydraulic resistance at the outlet of the discharge pipe 3 does not increase and, accordingly, there is no need to increase the drive power of the beet pump during its operation.

Beet-water mixture enters through the suction pipe 2 along the axis of the beet pump into the space between the rear 7 and front 6 disks of the rotating impeller. Due to the conical shape of the rear and front discs, the beet-water mixture smoothly changes the direction of movement from axial to radial, is captured by curved blades 8 made of composite material, and flows along the cylindrical surface of the housing 1 to the discharge pipe 3. Heavy and light impurities in the beet-water mixture collide with the main section 10 having a frame, for example, of a rigid metal structure, curved blades 8 and under the action of centrifugal forces move to the periphery of the slave what wheels. Impact energy is transmitted through a polymer elastic coating to the rubber-fabric shell 9 and then to the rigid structure of the main section 10. The implementation of curved blades 8 of composite material upon impact of both heavy and light impurities ensures the deformation of the assembly frame with the rubber-fabric shell 9, preventing intense damage to the beets. As a result, part of the impact energy of heavy and light impurities of the beet-water mixture is absorbed by the wear-resistant elements of the curved blades 8, and the rest is returned to the impacted impurities and the fluid flow, providing a given pressure of the beet pump.

Heavy and light impurities that have moved to the periphery of the impeller act on the shank 11, which has a flexible frame structure, for example, made of a metal mesh, located in the rubber-fabric shell 9 and coated with an elastic material. As a result, an elastic deviation of the shank 11 is observed, which is ensured for any direction of impact of heavy and light impurities, which virtually eliminates jamming of the flexible blades 8.

When the random and probabilistic nature of the ingress of heavy and light impurities during the rotation of the impeller between the housing 1 and the shank 11, the latter elastically deviates, as if rolled over the impurity, and dumps it into the volume of beet-water mixture, determined by the blade 8, following the rotation of the impeller, disks 6 and 7, as well as the housing 1. As a result, the jamming conditions of the beet pump, which were observed when curved blades 8 were made on a continuous rigid basis, are eliminated.

Due to the influence of 8 heavy and light impurities in the beet-water mixture on the curved blade, the pressure plots on the working and back sides of the blade are slightly different from each other. To eliminate this phenomenon, on the shank 11 on the surface of the rubber-fabric shell 9 covered with elastic material, curved grooves 13 are made, converging to the exit of the curved blades 8. As a result, due to the pressure difference on the working and back surfaces of each blade 8, the beet-and-water mixture is helically longitudinally arranged The grooves 13 flow from a surface with a higher pressure to a surface with a lower pressure. In this case, the pressure plots along the blades 8 are aligned with each other, as a result of which the resulting pressure force acting on the impeller is reduced, reducing the vibration of the wheel. The geometry of the curvature of the helical grooves 13 is adjusted to the curvature of the blade so that together they form a curved crescent-shaped profile of the shank 11 continuously tapering towards the exit. Due to this, stall edge phenomena behind the cavities 8 of the impeller are eliminated or significantly reduced, not only the pressure loss in the beet pump is reduced, but also pulsations of static pressure under the impact of heavy and light impurities on the surface of the blades.

The originality of the invention lies in the fact that the execution of curved grooves, both on the shank of a curved impeller blade and on the inner surface of the discharge pipe with a mutually opposite direction of movement of a moving water stream with heavy and light impurities during transportation of beets, ensures the elimination of pollution and a corresponding increase in hydraulic resistance during operation of the beet pump, which ultimately supports the normalized mode of its long-term operation.

Providing a beet pump with a drive with a speed controller in the form of a block of powder electromagnetic couplings and an automated pressure control system in the discharge pipe provides flexible energy consumption for the rotation of the impeller shaft, which ultimately results in the presence of heavy and light impurities in the water flow.

Claims (1)

A beet pump containing a housing with suction and discharge nozzles and an impeller cantilever mounted on the shaft, consisting of front and rear disks in the form of cones and curved blades mounted between them, coatings made of elastic material are placed on the inner surface of the housing and the surfaces of the impeller, while the impeller blade is made of composite material, which includes a rubber-fabric shell and a prefabricated frame containing a main section representing a rigid structure and a skeleton representing a flexible design, and the rubber-fabric shell is evenly distributed throughout the entire volume of the prefabricated frame, and on the shank along the surface of the rubber-fabric shell coated with elastic material, curved grooves are made that converge to the exit of the curved blade, while curved grooves are made on the inner surface of the discharge pipe, the tangent of which has a clockwise direction, and the tangent of curved grooves on the shank along the surface of the rubber-fabric shell has a counterclockwise direction, characterized in that the impeller shaft is equipped with a drive with a speed controller, and the speed controller is connected to a pressure controller connected to a pressure sensor located in the discharge pipe, while the pressure controller contains interconnected comparison and task units , electronic and magnetic amplifiers and a non-linear feedback block, in addition, the speed controller is made in the form of a block of powder electromagnetic couplings.

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