RU2194881C1 - Inclined archimedean screw pump for removing viscoplastic and ooze-and-sand masses (versions) - Google Patents

Abstract

FIELD: pumps. SUBSTANCE: invention can be used for cleaning aeration tanks of sewage works, containers with vegetable oil sediments, tanks with residual fuel oil, manure heaps, etc and as hand tool of divers or rescuers of ESM service at clearing ooze and mudflow drifts. Proposed screw pump has housing in cylindrical space of which screw is installed for movement. Screw has single-start thread at its input and multiple-start part of screw blades at its output. Single-start part is enclosed in blade feeder which has shafts coaxial with screw and different rotation speeds, shafts being connected with coaxial output shaft of reduction gear. Input shaft of reduction gear is connected with drive. Feeder is enclosed in fixed lattice housing. blade of single-start part of screw is provided with flange over outer perimeter at site of housing. Said flange is secured on blade lifting surface at angle from 90^° to 140^° with possibility of changing of changing the height from 10% to 60% of pitch of single-start part. Sense of feeder rotation coincides with sense of screw rotation. Ratio of screw rotation speed to feeder rotation speed is from 1.5 to 40. EFFECT: provision of high capacity at handling viscoplastic and ooze-and-sand masses, reduced power consumption and metal usage at manufacture of pump. 10 cl, 9 dwg

Description

 The invention relates to a technique for cleaning and pumping various viscoplastic and silt-sand masses and can be used for cleaning aerotanks of water treatment plants, for pumping gel-like masses in the food industry, for example, sludge of vegetable oil from storage tanks, as well as in the petrochemical industry, for example, for cleaning fuel oil from tanks, in agricultural production, for example, for clearing manure accumulations at poultry farms, as well as a manual tool for a diver or rescue service of the MCH when clearing the silt and mud drifts.

 Known auger pumps for viscous-plastic media having a cylindrical body in which a screw is installed, part of which protrudes from the body and is covered by a blade feeder having a counter-rotating direction of rotation and a different speed with the screw [1], [2].

 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.

 The closest technical solution, selected as a prototype [3], is a screw pump for viscous-plastic masses made of a cylindrical body in which a movable screw is installed, having a single-entry at the mass inlet and a multi-start screw blades at the mass exit, with a single-start part encompassed by a blade feeder having coaxially arranged shafts with an opposite direction and a different speed with a screw connected to a coaxial output shaft of the gearbox, the input shaft of which is connected drive.

 A disadvantage of the known pump is the impossibility of obtaining high performance when pumping viscoplastic and especially silt-sand masses due to the fact that with a high rotational speed of the screw on the part that protrudes from the housing and is covered by the feeder, significant inertial forces arise, which discharge most of the feed mass from a single-running auger blade, thereby reducing the amount of incoming mass into the body. In addition, a high relative peripheral speed arises from counter motion of the mass by the feeder and auger, which in quadratic dependence forms the drag force of the feeder blades, increasing the power consumption of the pump.

 The problem to which the invention is directed is to achieve high-performance pumping of both viscoplastic and silt-sand masses, as well as to reduce the energy consumption and metal consumption of the pump.

This is achieved by the fact that a screw pump for cleaning viscoplastic and silt-sand masses, made of a casing, in the cylindrical cavity of which a movable screw is installed, having a single-input at the input and a multi-input part of screw blades at the output, while the single-use part is covered by a blade feeder having with a screw, coaxially placed shafts and various speeds, the latter are connected to the coaxial output shaft of the gearbox, the input shaft of which is connected to the drive, and the feeder is covered by a fixed trellis zhuhom, and a vane a single-pass portion of the screw on the outer circumference with the housing side is provided with fixed to it a lifting surface of a board at an angle of 90 ^o - 140 ^o to vary its height from 10 to 60% of the step single-pass portion, the direction of rotation of the feeder is combined with the direction of rotation of the screw, and the ratio of the frequency of rotation of the screw to the frequency of rotation of the feeder is 1.5 - 40.0. In addition, the multi-start part of the auger is made of two-way, and the board is attached to the lifting surface of the one-way auger blades, for example by welding, and is equipped with threaded holes for installation of height-adjustable side nozzles. A gas engine is installed as a drive, and a sliding bearing is installed between the housing and the feeder, and the blade feeder contains two symmetrically located side and end blades. In addition, the ratio of the rotational speed of the screw to the rotational speed of the feeder is 16.5.

The screw pump for cleaning viscous-plastic and silt-sand masses is made in the form of a device from a cylindrical body, in which the two-way part of the screw is placed, and its one-way part with the side is located outside the body, while the board is attached to the lifting surface of the single-way auger blade with a smaller diameter than the outer diameter of the blade, and at an angle of more than 90 ^o and with the possibility of changing the bead height from 10 to 60% of the step size of the one-way part of the screw, and the drive shaft of the screw is connected to the output shaft of the gearbox, the input shaft of which th connected to the drive. The bead can be attached to the lifting surface of the blade with a radius smaller than the radius of the outer perimeter of the blade and at an angle of more than 90 ^o , and the screw shaft is made hollow from a pipe equipped with a bearing at the end of the single-start part, connected along the axis with the bottom of the trellised casing.

 The invention is illustrated by drawings, where figure 1 shows a General view of the pump according to the first embodiment, made in the form of a hand tool with a drive from a gas engine; figure 2 shows a part of the auger protruding from the housing with a single-entry screw blade, to which a fastening and extension board is attached (this part of the auger is covered by a two-blade feeder having the same direction of rotation with the auger); figure 3 shows a cross section of the screw aa and its single-blade blade; figure 4 shows a section bB of the breakout of a single-entry blade with a mounting and extended side; figure 5 shows a General view of a pump made in the second embodiment; figure 6 shows a one-way part of the screw covered by a protective casing, and part of the housing; figure 7 shows a section bb of the single-entry part of the screw; in Fig.8 shows a section GG of the pullout of a single-entry blade with a mounting flange and a removable flange of greater height screwed to it; figure 9 shows the end face of the screw with a bearing and an axis.

 The screw pump device of FIG. 1 constructively consists of a housing 1, in the cylindrical cavity of which a movable screw is installed, having a single-start part 2 and a multi-start part 3. The single-start part 2 is covered by a blade feeder 4 having coaxially arranged shafts with the screw: screw shaft 5 and shaft blade feeder 6, which are connected to the output shaft of the gearbox 7, the input shaft of which is connected to the drive 8. The feeder 4 is covered by a trellised casing 9. The blade 10 of the single-start part 2 along the outer perimeter from the side of the housing 1 is provided with captive to the lifting surface 11 side 12. Using threaded elements 13 to the side 12 is attached a removable side nozzle 14. Between the housing 1 and the feeder 4 is installed a sliding bearing 15. The feeder 4 is made of two side blades 16 and two end blades 17. Drive 8 ( gas engine) is equipped with a tank 18 for fuel, and the housing 1 is equipped with handles 19 for holding and controlling the pump.

The screw pump device of FIG. 5 constructively consists of a housing 20, in the cylindrical cavity of which a movable screw is installed, having a single-start part 21 and a multi-start part 22. The drive shaft 23 of the screw is connected to a gearbox 24, the input shaft of which is connected to the drive 25. The multi-start part 22 the auger is housed in the housing 20, and the one-way part 21 is enclosed by a trellised casing 26. The blade 27 of the one-way part 21 from the side of the housing 20 is provided with a flange 29 attached to its lifting surface 28. The bead 29 is attached to the lifting surface 28 the radius R ₂ , which is less than R ₁ , the radius of the blade 27, and the board 29 with respect to the surface 28 is attached at an angle α ₂ = 130 ^o . An extension board 31 is attached to the board 29 by means of threaded elements 30. The screw shaft 23 is hollow, at the end of which a bearing 32 is mounted, which is connected through the axis 33 to the bottom 34 of the casing 26. The drive 25 (gas engine) is equipped with a fuel tank 35, and the housing 20 is equipped with handles 36.

The coated board 31 gives an increase in the diameter of the one-way screw part 21 to a radius value of R ₃ , which provides a large area of frontal contact of the input part 21 with the mass being cleaned and thus provides an increase in pump performance.

 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 9 into a plastic or silt-sand mass. Moreover, if the mass to be cleaned has a low viscosity, for example, oil or suspended sludge, then such a mass will by gravity fill the entire space around the single-pass part 2 of the screw. After turning on the gas engine 8, the torque from its shaft is transmitted to the input shaft of the gearbox 7, which has two coaxially placed output shafts. The female tubular shaft 5 provides rotation of the screw with a peripheral speed V ₁ , and the male shaft 6 provides rotation of the blade feeder 4 with a peripheral speed V ₂ . The side blades 16 of the feeder 4 capture, guide and press the mass to the inlet part 2 of the screw. In this case, the mass, falling on the lifting surface 11 of the blade 10, having a lifting angle β, is in the field of centrifugal force from the rapidly rotating shaft 5 of the screw. The action of centrifugal force presses the mass to the periphery of the blade 10, and since the periphery of the blade 10 has a mounting board 12 and an extension board 14 having a certain height h with respect to the step S of the single-auger part of the screw, then the entire mass limited by the height h of the extended side 14 remains on the lifting surface 11 of the blade 10 and begins to move upward along it at an angle β towards the housing 1 due to the inertial lag of the rotating pumped mass from the denser mass of the screw. Next, the mass enters the outlet part 3 of the screw, limited by the housing 1, where increased hydraulic pressure is created, and the mass is squeezed out through the nozzle into the transporting pressure hose.

 The pump of FIG. 5 operates as follows.

 The pump is taken by the operator by the handles 36 and is buried by the trellised casing 26 into a liquid or plastic mass, which by gravity or by running over with a pump will fill the entire space around the one-way part 21 of the screw. After turning on the gas engine 25, the torque from its shaft is amplified by the gearbox 24 and ensures the rotation of the screw. The mass to be cleaned in the rotation zone of the inlet part of the screw 21 undergoes 1) the impact of the lifting surface 28, which moves this mass along the screw channel towards the housing 20, and also 2) the effect of centrifugal force, which presses the mass to the board 31, which stores the mass in the screw channel the single-start part 21 until it enters the area of the multi-start part 22 of the screw and further into the pipe and the transporting pressure hose.

 The screw pump device of FIG. 1 is most suitable for stripping and pumping such plastic masses as, for example, solid oil, lithol, animal fats, thick sludge and other non-Newtonian liquids with weak independent fluidity. For high-performance work with such masses, the pump must be constantly moved so that the one-way part 2 is constantly filled with mass, that is, it is necessary to constantly run into the mass being cleaned. In such cases, it is more advisable to attach the pump to a special trolley, moved and controlled by the operator, cleaning, for example, a certain sector of the area, or moving the pump manually if it is made in the form of a hand tool.

 The screw pump arrangement of FIG. 5 it is advisable to use for pumping such Newtonian masses that have independent fluidity, such as water, and milk, and vegetable oil, as well as oil, suspended sludge and other liquids.

 In addition, the pump of FIG. 5 is structurally simpler than the pump of FIG. 1 and, as a result, is less metal and energy intensive, therefore, it is preferable to manufacture it in the form of a hand tool.

Sources of information taken into account
1. USSR author's certificate "Screw pump for visco-plastic media" 513169, F 04 D 3/02.

 2. USSR copyright certificate "Screw pump for visco-plastic media" 1132061, F 04 D 3/02.

 3. Patent of Russia "Screw pump for visco-plastic masses" 2143591, F 04 D 3/02 of 12/27/1999

Claims (10)

1. A screw pump for cleaning viscoplastic and silt-sand masses, made of a casing, in the cylindrical cavity of which a movable screw is installed, having a single-input at the input and a multi-input part of screw blades at the output, while the single-input part is covered by a blade feeder having coaxially with the screw placed shafts and various speeds, the latter are connected to the coaxial output shaft of the gearbox, the input shaft of which is connected to the drive, and the feeder is covered by a fixed trellised casing, characterized by m, that the blade of the single-running part of the screw along the outer perimeter from the side of the body is equipped with a side attached to its lifting surface at an angle of 90 - 140 ^o with the possibility of changing its height from 10 to 60% of the pitch of the single-running part, while the direction of rotation of the feeder is aligned with the direction screw rotation and the ratio of screw speed to feeder speed is 1.5 - 40.0.  2. The screw pump according to claim 1, characterized in that the multi-start part of the screw is made double-start.  3. The screw pump according to claim 1, characterized in that the board is attached to the lifting surface of the single-entry auger blades, for example, by welding, and is equipped with threaded holes for installing on-board nozzles that are replaceable in height.  4. A screw pump according to claim 1, characterized in that a gas engine is installed as a drive.  5. The screw pump according to claim 1, characterized in that a plain bearing is installed between the housing and the feeder.  6. The screw pump according to claim 1, characterized in that the blade feeder contains two symmetrically located side and end blades.  7. The screw pump according to claim 1, characterized in that the ratio of the rotational speed of the screw to the rotational speed of the feeder is 16.5. 8. A screw pump for cleaning viscoplastic and silt-sand masses, made in the form of a device from a cylindrical body, in which the two-way part of the screw is placed, and its one-way part with the side is placed outside the body, characterized in that the board is attached to the lifting surface of the single-way auger blade smaller diameter than the outer diameter of the blade, and at an angle greater than 90 ^o and with the possibility of changing the bead height from 10 to 60% of the pitch of the single-entry part of the screw, and the drive shaft of the screw is connected to the output shaft of the gearbox, whose input shaft is connected to the drive. 9. A screw pump according to claim 8, characterized in that the board can be attached to the lifting surface of the blade along a radius smaller than the radius of the outer perimeter of the blade and at an angle greater than 90 ^o .  10. A screw pump according to claim 8, characterized in that the screw shaft is made hollow from a pipe equipped with a bearing at the end of the single-start part, connected along the axis with the bottom of the trellised casing.

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