RU2241856C2 - Inclined archimedean screw pump (versions) - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: invention relates to screw pumps used as hand tools with self-contained drive or installed on wheeled cart and designed for handling any liquids, including, viscous, plastic and viscoplastic materials. Inlet part of screw has less number of screw blades than outlet part. Screw is connected with drive through reduction gear. Outlet part is arranged in cylindrical space of housing. Inlet part of screw projecting from housing is enclosed by fixed screen casing. Blades of inlet part are provided with beads, outlet branch pipe is connected to housing tangentially, and end faces of blades of screw outlet part are tightly connected with disk whose diameter is equal to diameter of screw blades. Disk is rigidly connected to screw shaft. Additional plates are symmetrically connected to disk and screw shaft in spaces between blades of outlet part. Length of plates does not exceed width of channels between blades of outlet part, and their height does not exceed radius of disk.

EFFECT: increased capacity of pump operating at high head with simultaneous decrease of power consumption.

12 cl, 6 dwg

Description

The invention relates to techniques for both volumetric and dynamic screw pumps, made in the form of a light hand tool with an independent drive, or a heavy device mounted on a wheeled trolley, and can be used for pumping any liquids, as well as viscous, plastic and viscoplastic masses, for example water, milk, alcohol, honey, sludge, vegetable oil, dough, butter, as well as gasoline, kerosene, free-flowing oil, thickened oil, industrial fats, solid oil, fuel oil, mortar, foam eton, river sludge, etc. The pump can be controlled by one production worker or a robot manipulator. In addition, the pump can be used by the rescuer of the Ministry of Emergencies in the aftermath of natural disasters during floods, during the cleaning of oil emissions on the coastline, as well as by fishermen and sailors to pump water from the vessel that received the breach.

Known auger pumps for visco-plastic media having a cylindrical housing in which a screw is installed, part of which protrudes from the housing and is covered by a blade feeder having a counter-rotating direction of rotation and a different rotation frequency with the screw (Russian patent No. 2143591, M. class. F 04 D 3 / 02, 7/00 and Russian patent No. 2177087, M. cl. F 04 D 3/02, 7/00).

The disadvantage of such pumps is that a high relative peripheral speed arises from oncoming mass movement by the blade feeder and screw, which in quadratic dependence forms the drag force of the feeder blades, increasing the power consumption of the pump. In addition, such pumps have an outlet pipe installed end-to-end to the housing, i.e. so that the axis of the housing and the axis of the outlet pipe intersect, which increases the hydraulic resistance. These well-known pumps ensure that the mass is pushed into the outlet pipe only by the main blades of the screw, in addition, in such pumps, the mass moving along the body axis with great effort is pressed into the stationary end of the body before entering the outlet pipe, which also creates a large hydraulic resistance. And the presence of a gearbox for a low-speed drive of a blade feeder increases the mass of the pump, which becomes unacceptable as a hand tool.

The closest technical solution, selected as a prototype, is a screw pump for cleaning viscoplastic and silt-sand masses (Russian patent No. 2194881, Mcl 7/00, 3/02), containing a housing equipped with an outlet pipe and a screw placed movably in the housing, the screw having an input part with a smaller number of screw blades and an output part with a large number of screw blades is connected by a shaft through a gearbox with a drive, in addition, the output part of the screw is placed in a cylindrical cavity of the housing, and the input part of the screw , The blades of which are made with flanges and projecting from the housing, the housing is covered by a fixed trellis. The bead is attached to the lifting surface of the one-way blade at a smaller diameter than the diameter of the blade, and at an angle greater than 90 °, and the side height can be from 10 to 60% of the pitch of the one-way part.

A disadvantage of the known pump is the inability to obtain high performance due to the fact that the outlet pipe is connected to the body end-to-end, so that their axes intersect. In addition, the ejection of the mass into the outlet pipe is carried out only by two blades of the two-way outlet part of the screw. And since the mass pushed into the outlet pipe constantly contacts the stationary wall of the pump casing, a large hydraulic resistance is created, which increases the power consumption. In addition, the type of mechanical seal in the prototype used typical labyrinth technical solutions and industrial rubber cuffs, which also create significant mechanical friction resistance along the neck of the screw shaft and also increase the power consumption of the pump. And for pumping such liquids as water, the prototype pump cannot provide large head values, since it does not have an annular chamber to hold a continuous, continuous, rotating fluid flow.

The problem to which the invention is directed, is to increase the productivity of the pump for pumping liquids with high pressure, as well as viscous-plastic masses while reducing the energy consumption of the pump.

This is achieved by the fact that in a screw pump for pumping liquids and viscous-plastic masses, comprising a housing provided with an outlet pipe and a screw located movably in the housing, the screw having an inlet part with fewer screw blades and an outlet part with a large number of screw blades is connected using the shaft through a gearbox with a drive, in addition, the output part of the screw is placed in the cylindrical cavity of the housing, and the input part of the screw, the blades of which are made with sides and protruding from the housing, is covered by a fixed solution According to the invention, the outlet pipe is connected tangentially to the body, and the ends of the blades of the outlet part of the screw are tightly connected to the disk, the diameter of which is equal to the diameter of the blades of the screw and which is rigidly attached to the shaft of the screw, and in the spaces between the blades of its output part to the disk and shaft of the screw additional plates are symmetrically attached, the length of which is not greater than the width of the channels between the blades of the outlet part of the screw, and their height is not greater than the radius of the disk, while the end face of the disk opposite from the blades is provided with with a smaller diameter than the disk and a polished end surface, to which an annular sliding bearing is connected through a lubricating film, connected to a flexible annular membrane that is attached to the housing, while the membrane with the bearing is pressed by the end of the compression cylindrical spring, and the second end of the spring attached to the housing, in addition, the end surface of the sliding bearing, movably in contact with the polished end of the ring, is provided with an average diameter of equidistant from each other along the perimeter about holes filled with grease, while an oil seal is installed between the disk and the housing. In this case, the sliding bearing can be made, for example, of bronze; the annular membrane can be made, for example, of stainless steel with a thickness of 0.1-0.3 mm; the connection of the sliding bearing with the membrane can be performed, for example, by flaring the first; the stuffing box can be made, for example, of fluoroplastic; the outer diameter of the plain bearing is commensurate with the diameter of the ring; the inlet part of the screw can be made, for example, single-entry; the output part of the screw can be performed, for example, two-way; and as a drive, for example, a gas engine can be used; and as a lubricant, a mixture of three parts of lithol and one part of graphite powder can be used.

According to the second embodiment, the task is solved in that in a screw pump for pumping liquids and viscous-plastic masses, comprising a housing provided with an outlet pipe and a screw located movably in the housing, the screw having an inlet part with fewer screw blades and an outlet part with a large the number of screw blades, connected via a shaft through a gearbox with a drive, in addition, the output part of the screw is placed in the cylindrical cavity of the housing, and the input part of the screw, the blades of which are equipped with sides stepping out of the casing, covered by a fixed lattice casing, according to the invention, the end part of the casing above the outlet of the screw is provided with a centrifugal chamber with a diameter larger than the casing than the casing, and the outlet pipe is tangentially attached to its side surface, while the axial width of the centrifugal chamber is equal to the width of the channel between the blades the output part of the screw, and the ends of the blades of the output part of the screw are tightly connected to the end of the centrifugal disk mounted on the shaft of the screw, the diameter of this disk being smaller than the internal diameter meter of the chamber, in addition, extension plates are rigidly attached to the blades of the outlet part of the screw in the volume of the centrifugal chamber, and in the spaces between the screws of the screw in the volume of the centrifugal chamber, the propeller blades are symmetrically attached to the centrifugal disk and the shaft of the screw, their length being less than the axial width of the chamber, and their the height and height of the blades of the outlet part of the screw in the volume of the centrifugal chamber is less than the radius of the centrifugal disk. The pump housing can be made, for example, cast or welded.

The invention is illustrated by drawings, where

Figure 1 shows a General view of the pump according to the first embodiment with sections and tears, made in the form of a hand tool driven by a gas engine.

In Fig.2 shows a section aa in Fig.1, explaining the tangential fastening of the outlet pipe.

Figure 3 shows an axial section of a part of the housing, an explanatory device of the mechanical seal and additional plates on the shaft of the screw.

Figure 4 shows a section bB in figure 3, illustrating the device of the mechanical end bearing.

Figure 5 shows a General view of a pump made in the second embodiment.

Figure 6 shows a section bb in figure 5, explaining the device and the placement of the centrifugal chamber and the centrifugal disk.

The screw pump device of FIG. 1 constructively consists of a cylindrical housing 1 having a tangential outlet pipe 2 rigidly attached to it. In the cylindrical cavity of the housing 1, a movable screw 3 is installed, having an input part 4 with a smaller number of screw blades and an output part 5 having a larger number of screw blades. The screw shaft 6 is connected via a gearbox 7 to the drive 8. The entire output, multi-blade part 5 of the screw 3 is located in the cylindrical part of the housing 1, and the input part 4 of the screw 3 is made with blades having sides 9, is located outside the housing 1 and is covered by a protective trellised casing 10 Thus, the ends of the blades of the output part 5 of the screw 3 are tightly connected to the disk 11, which has a diameter equal to the diameter of the blades of the screw. The disk 11 is also rigidly attached to the shaft 6 of the screw 3, and in the spaces between the blades of the outlet part 5 of the screw, additional plates 12 are attached. The end face of the disk 11 opposite from the blades of the screw is provided with a ring 13 having a diameter smaller than that of the disk 11. To the end polished surface of the ring 13, the annular end plain bearing 14, which is rigidly fixed to the flexible annular membrane 15, is pressed through the lubricating film. The outer diameter of the membrane 15 is rigidly and hermetically fixed to the housing 1. The membrane 15 together with the bearing 14 a compression coil spring 16, the second end of which is attached to the housing 1. In this case the end surface of a plain bearing 14 slidably in contact with a polished end face of the ring 13 is provided with a average diameter equidistant from one another blind bore 17 filled with an antifriction lubricant. In addition, between the disk 11 and the housing 1 is installed an oil seal 18. To operate the pump as a hand tool, it is equipped with handles 19.

The screw pump device of FIG. 5 is structurally composed of a housing 20 provided with an outlet pipe 21 and a screw 22, which is movably placed in the housing 20, the screw 22 having an inlet part 23 with fewer screw blades and an outlet part 24 with a large number of screw blades, connected by a shaft 25 through a gearbox 26 with a drive 27. In addition, the output part 24 of the screw 22 is located in the cylindrical cavity of the housing, and the input part 23 of the screw 22, the blades of which are provided with sides 28 and protruding from the housing 20, is covered by a fixed lattice casing 29. In this case, the end part of the casing 20 above the outlet part 24 of the screw is provided with a centrifugal chamber 30 with a diameter larger than the case 20, to the lateral surface of which the outlet pipe 21 is tangentially attached, while the axial width of the centrifugal chamber 30 is comparable with the width of the channel between the blades the outlet part 24 of the screw, and the ends of the blades of the outlet part 24 of the screw are tightly connected to the end face of the centrifugal disk 31 mounted on the shaft 25 of the screw, the diameter of the disk 31 being less than the inner diameter of the centrifugal chamber 30, and the center extension chamber 30 to the blades of the outlet part 24 of the screw extension plates 32 are rigidly attached, and in the spaces between the blades 24 of the screw, in the volume of the centrifugal chamber 30 to the centrifugal disk 31 and the shaft 25 of the screw, rowing blades 33 are symmetrically attached, the length of which is less than the axial width of the chamber 30 , and their height is less than the radius of the centrifugal disk 31. To operate the pump as a hand tool, it is equipped with handles 34.

The pump of figure 1 works as follows.

The pump is taken by the operator by the handles 19 and is buried by the trellised casing 10, for example, in the river sludge after the flood, the gas engine is turned on and with the help of the handles 19 the pump moves in the sludge mass, providing the most complete filling of the screw and the greatest productivity.

The screw pump device of FIG. 1 is most suitable for stripping and pumping such plastic or viscous-plastic masses, such as, for example, solid oil, lithol, thickened oil, vegetable oil sludge, river sludge, and other non-Newtonian liquids with low independent fluidity. For high-performance work with such masses, the pump must be constantly moved so that the inlet of the screw is constantly filled with mass.

The pump of FIG. 5 operates as follows.

The pump is taken by the operator by the handles 34 and buried by the trellised casing 29, for example, in river water after a flood, the gas engine is turned on and with the help of the handles 34 the pump is held in water or moved, for example, into flooded basements, containers, rooms, pumping water out of them together with silt.

The screw pump device of FIG. 5 is more expedient to use liquids such as water, gasoline, kerosene, oil, suspended sludge, milk, vegetable oil and other liquids for high-performance pumping with high pressure.

Claims (12)

1. A screw pump for pumping liquids and viscous-plastic masses, made of a housing equipped with an outlet pipe and a screw located movably in the housing, the screw having an inlet part with fewer screw blades and an outlet part with a large number of screw blades is connected via a shaft through a gearbox with a drive, in addition, the outlet part of the auger is located in the cylindrical cavity of the housing, and the inlet protruding from the housing, the part of the auger, the blades of which are made with sides, is covered by a fixed lattice casing, excellent which is that the outlet pipe is connected tangentially to the body, and the ends of the blades of the outlet part of the screw are tightly connected to the disk, the diameter of which is equal to the diameter of the blades of the screw and which is rigidly attached to the shaft of the screw, and in the gaps between the blades of its output part to the disk and shaft of the screw additional plates are attached, the length of which is not greater than the width of the channels between the blades of the outlet part of the screw, and their height is not greater than the radius of the disk, while the end face of the disk opposite from the blades is provided with a ring with a smaller diameter than suit, with a diameter and a polished end surface, to which an annular sliding bearing is connected through a lubricating film, connected to a flexible annular membrane that is attached to the housing, while the membrane with the sliding bearing is pressed by the end of the cylindrical compression spring, and the second end of the spring is attached to the housing, except Moreover, in the end surface of the sliding bearing movably in contact with the polished end face of the ring, through holes are made equally spaced apart from each other, filled grease, while a seal is installed between the disk and the housing. 2. The pump according to claim 1, characterized in that the plain bearing is made of bronze. 3. The pump according to claim 1, characterized in that the annular membrane is made of stainless steel with a thickness of 0.1-0.3 mm 4. The pump according to claim 1, characterized in that the connection of the sliding bearing with the membrane is made by flaring the first. 5. The pump according to claim 1, characterized in that the oil seal is made of fluoroplastic. 6. The pump according to claim 1, characterized in that the outer diameter of the annular plain bearing is commensurate with the diameter of the ring. 7. The pump according to claim 1, characterized in that the inlet part of the screw is made single-entry. 8. The pump according to claim 1, characterized in that the output part of the auger is made double-entry. 9. The pump according to claim 1, characterized in that a gas engine is used as a drive. 10. The pump according to claim 1, characterized in that as a lubricant used a mixture of three parts of lithol and one part of graphite powder. 11. A screw pump for pumping liquids and viscous-plastic masses, made of a housing equipped with an outlet pipe and a screw placed movably in the housing, the screw having an inlet part with fewer screw blades and an outlet part with a large number of screw blades connected by a shaft through a gearbox with a drive, in addition, the outlet part of the auger is placed in the cylindrical cavity of the housing, and the inlet part of the auger protruding from the housing, the blades of which are provided with sides, is covered by a fixed lattice casing, I distinguish in that the end part of the housing above the outlet part of the screw is provided with a centrifugal chamber with a diameter larger than the case of the housing to the side surface of which the outlet pipe is tangentially attached, while the axial width of the centrifugal chamber is comparable with the width of the channel between the blades of the outlet part of the screw, and the ends of the blades the output part of the screw is tightly connected to the end of the centrifugal disk mounted on the shaft of the screw, and the diameter of this disk is less than the inner diameter of the centrifugal chamber, in addition, in the volume of the centrifugal chamber Extension plates are rigidly attached to the blades of the outlet part of the screw, and in the intervals between the blades of the screw in the volume of the centrifugal chamber, rowing blades are symmetrically attached to the centrifugal disk and the shaft of the screw, their length being less than the axial width of the chamber, and their height and the height of the blades of the outlet part of the screw in volume the centrifugal chamber is smaller than the radius of the centrifugal disk. 12. The pump according to claim 9, characterized in that the housing is molded or welded.

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