RU236043U1 - Screw pump - Google Patents

Abstract

The utility model relates to designs of screw pumps intended for pumping highly viscous, multiphase, aggressive materials in the oil, chemical, food, construction and other industries. The technical result is achieved due to the fact that the screw pump contains a housing with drive and sealing screws installed in it and made with the possibility of rotation in the opposite direction, containing turns and grooves, wherein the drive screw contains a modified section at the base of the turn, and the sealing screw contains a modified section at the edge of the top of the turn. The drive screw comprises a modified section at the base of the turn, formed in the cross-section by a smooth conjugation of the surface of the working profile of the drive screw turn, the transition curve of the profile of the drive screw turn and the arc of the inner diameter of the groove of the drive screw, and the sealing screw comprises a modified section at the edge of the top of the turn, formed in the cross-section by a smooth conjugation of the surface of the working profile of the sealing screw turn, the transition curve of the profile of the sealing screw turn and the arc of the outer diameter of the sealing screw turn. The technical result of this utility model is to increase the reliability of the pump.

Description

The utility model relates to the designs of screw pumps intended for pumping highly viscous, multiphase, aggressive materials in the oil, chemical, food, construction and other industries.

A device for transmitting working fluid is known, consisting of two interacting screws with opposite pitch and rotating in the opposite direction, tightly surrounded by a housing (patent US 1698802 A). In this technical solution, increased stress is generated in the mating zone of the screw surfaces during engagement, which leads to increased wear of the screws.

A device for pumping working fluid is known, consisting of two interacting screws with opposite pitch and rotating in the opposite direction, tightly surrounded by a housing. The screws act together as a piston, which, when rotating, moves the liquid inside the housing in the direction along the axis of the screws (patent US 2198786 A). In this technical solution, increased stress is generated in the mating area of the screw surfaces during engagement, which leads to increased wear of the screws, as a result of which the reliability of the pump decreases.

The closest technical solution adopted as a prototype is a pump containing a housing with drive and sealing screws installed in it and configured to rotate in opposite directions, containing turns and screw grooves, wherein the drive screw contains a modified section at the base of the turn, and the sealing screw contains a modified section at the edge of the top of the turn (patent CN 102352840 A).

The technical problem that the proposed utility model is aimed at solving is the elimination of the shortcomings of the state of the art and the creation of a screw pump with increased strength and wear resistance of the screws due to modified sections of the screw surfaces of the screws.

The technical result of this utility model is to increase the reliability of the screw pump.

The proposed screw pump comprises a housing with drive and sealing screws installed in it and configured to rotate in the opposite direction, containing turns and grooves.

The stated problem is solved, and the technical result is achieved due to the fact that the modified section of the drive screw is formed in the cross-section by the conjugation of the surface of the working profile of the turn of the drive screw, the transition curve of the profile of the turn of the drive screw and the arc of the inner diameter of the groove of the drive screw, and the modified section of the sealing screw is formed in the cross-section by the smooth conjugation of the surface of the working profile of the turn of the sealing screw, the transition curve of the profile of the turn of the sealing screw and the arc of the outer diameter of the turn of the sealing screw, due to which the strength and wear resistance of the screw surfaces of the pump screws are increased. Moreover, the transition curve of the profile of the turn of the drive screw is formed by a smoothly conjugated arc of a circle of the turn of the drive screw and a section of a straight line, the radius of the arc of a circle of the turn of the drive screw is located in the range from 0.05 dН to 0.1 dН, where dН is the outer diameter of the screw, the length of the section of a straight line is located in the range from 0 dН to 0.02 dН, where dН is the outer diameter of the screw, and the transition curve of the profile of the turn of the sealing screw is formed by two smoothly conjugated arcs of circles, the radius of one of the arcs of circles of the turn of the sealing screw is located in the range from 0.055 dН to 0.11 dН, and the other - in the range from 0.015 dН to 0.025 dН, where dН is the outer diameter of the screw, which makes it possible to reduce the stress level arising in particularly stressed areas of the screws during operation, and, consequently, to increase the strength of the screws.

The essence of the utility model is explained by drawings:

Fig. 1 shows a screw pump in longitudinal section.

Fig. 2 shows a screw pump in cross section A-A.

Fig. 3 - remote element B, enlarged sectional view of modified sections of the drive and sealing screws.

Fig. 4 shows the extension element B, an enlarged sectional view of the modified section of the drive screw.

Fig. 5 - remote element G, enlarged sectional view of the modified section of the sealing screw.

The following positions are indicated on the figures: 1 - housing, 2 - drive screw, 3 - sealing screw, 4 - working profile of the drive screw turn, 5 - arc of the inner diameter of the drive screw groove, 6 - arc of the circumference of the drive screw turn, 7 - straight section, 8 - working profile of the sealing screw turn, 9 - arc of the outer diameter of the sealing screw turn, 10 - arc of the circumference of the sealing screw turn, 11 - arc of the circumference of the sealing screw turn, 12 - suction cavity, 13 - discharge cavity.

The screw pump comprises a housing 1 with drive and sealing screws 2, 3 installed therein and configured to rotate in the opposite direction, containing turns and grooves located in the bores of the housing 1 and in epicycloidal engagement. The drive and sealing screws 2, 3 contain modified sections (Fig. 3).

The drive screw 2 comprises a modified section (Fig. 4) at the base of the turn, formed in the cross-section by a smooth conjugation of the surface of the working profile of the turn 4 of the drive screw 2, the transition curve of the profile of the turn of the drive screw 2 and the arc 5 of the inner diameter of the groove of the drive screw 2. The transition curve of the profile of the turn of the drive screw 2 is formed by a smoothly conjugated arc of a circle 6 of the turn of the drive screw 2 and a section of a straight line 7. The section of a straight line 7 is a generatrix between the working profile of the turn 4 of the drive screw 2 and the arc of a circle 6 of the turn of the drive screw 2. The length of the section of a straight line 7 is preferably located in the range from 0 dн to 0.02 dн, where dн is the outer diameter of the screw. The radius R ₁ of the arc of a circle 6 of the turn of the drive screw 2 is preferably located in the range from 0.05 dН to 0.1 dН,

The sealing screw 3 comprises a modified section (Fig. 5) at the edge of the turn apex, formed in cross section by a smooth conjugation of the surface of the working profile of the turn 8 of the sealing screw 3, the transition curve of the profile of the turn of the sealing screw 3 and the arc 9 of the outer diameter of the turn of the sealing screw 3. The transition curve of the profile of the turn of the sealing screw 3 is formed by two smoothly conjugated arcs of circles 10, 11 of the turn of the sealing screw 3 at the apex of the edge of the turn of the sealing screw 3. Preferably, the radius R ₂ of the arc of circles 9 of the turn of the sealing screw 3 is selected in the range from 0.055 dН to 0.11 dН, and the radius R ₃ of the arc of circle 10 is in the size range from 0.015 dН to 0.025 dН, where dН is the outer diameter of the screw.

The screw pump works as follows.

Liquid is supplied to the suction cavity 12, which fills the cavities between the turns and moves along the axis of the housing 1 by rotating screws one step per one revolution of the drive screw 2. Most of the turns are constantly engaged during the operation of the pump. Liquid passes along the entire length of the screws 2, 3 of the housing 1 and enters the discharge cavity 13 from the pump. In this case, the outgoing liquid from the screws 2, 3 has a uniform movement. The pump operates without significant shocks and noise.

The technical solution is applicable in the design of twin-screw pumps with epicycloidal engagement, with a capacity from 1 ^m3 /hour to 900 ^m3 /hour, a pressure from 1 to 32 bar, a power from 0.3 kW to 800 kW, an efficiency from 0.5 to 0.98, an idle power from 0.06 kW to 200 kW, a working environment with a liquid viscosity from 0.1 cSt to 2000 cSt, with an external screw diameter in the range from 30 mm to 190 mm.

During the modeling process, it was revealed that the use of specified parameter ranges on the modified sections of the wire and sealing screws when using d _n > 190 mm showed that the pump screws could fail, which would significantly reduce its operating efficiency, and when using d _n < 30 mm, the pump would not operate effectively.

As an example of implementation, calculations of the parameters of the modified sections are given for the range of the external diameter _dн of the drive and sealing screws from 30 mm to 190 mm. With these values, the radius R ₁ of the arc of circles, which is located in the range from 0.05 dн to 0.1 dн, can be selected within the range from 1.5 mm to 19 mm, while the length of the straight section, located in the range from 0 dн to 0.02 dн, can be selected within the range from 0 mm to 3.8 mm. The value of the radius R ₂ of the circular arc, which is located in the range from 0.055 dН to 0.11 dН, can be selected in the range from 16.5 mm to 20.9 mm, and the radius R ₃ of the circular arc, which is located in the range from 0.015 dН to 0.025 dН, can be selected in the range from 0.45 mm to 4.75 mm.

During the modeling process, it was found that the use of the specified parameters of the modified sections below the specified ranges does not lead to a significant reduction in stresses in the specified sections, thus, the technical result is not achieved. The use of the specified parameters of the modified sections above the specified ranges is also inappropriate, since in this case the increase in reliability due to the reduction in stresses is reduced to zero, but the geometry of the screws also deteriorates, which causes a significant decrease in the efficiency of the pump.

This technical result is achieved due to the fact that the modified section of the drive screw is formed in the cross-section by the conjugation of the surface of the working profile of the turn of the drive screw, the transition curve of the profile of the turn of the drive screw and the arc of the inner diameter of the groove of the drive screw, and the modified section of the sealing screw is formed in the cross-section by the smooth conjugation of the surface of the working profile of the turn of the sealing screw, the transition curve of the profile of the turn of the sealing screw and the arc of the outer diameter of the turn of the sealing screw, wherein the transition curve of the profile of the turn of the drive screw is formed by a smoothly conjugated arc of a circle of the turn of the drive screw and a section of a straight line, the radius of the arc of a circle of the turn of the drive screw is located in the range from 0.05 dН to 0.1 dН, the length of the section of a straight line is located in the range from 0 dН to 0.02 dН, and the transition curve of the profile of the turn of the sealing screw is formed by two smoothly conjugated arcs of circles, the radius of one of the arcs The circumference of the sealing screw thread is in the range from 0.055 dН to 0.11 dН, and the other is in the range from 0.015 dН to 0.025 dН, where dН is the outer diameter of the screw.

Claims (1)

A screw pump comprising a housing with drive and sealing screws installed therein and configured to rotate in the opposite direction, comprising turns and grooves, wherein the drive screw comprises a modified section at the base of the turn, and the sealing screw comprises a modified section at the edge of the turn apex, characterized in that the modified section of the drive screw is formed in the cross-section by the conjugation of the surface of the working profile of the turn of the drive screw, the transition curve of the profile of the turn of the drive screw and the arc of the inner diameter of the groove of the drive screw, and the modified section of the sealing screw is formed in the cross-section by a smooth conjugation of the surface of the working profile of the turn of the sealing screw, the transition curve of the profile of the turn of the sealing screw and the arc of the outer diameter of the turn of the sealing screw, wherein the transition curve of the profile of the turn of the drive screw is formed by a smoothly conjugated arc of a circle of the turn of the drive screw and a section of a straight line, the radius of the arc of a circle of the turn of the drive screw is located in the range from 0.05 dН to 0.1 dН, where dН is the outer diameter of the screw, the length of the straight line section is in the range from 0 dН to 0.02 dН, where dН is the outer diameter of the screw, and the transition curve of the profile of the sealing screw turn is formed by two smoothly conjugate arcs of circles, the radius of one of the arcs of circles of the sealing screw turn is in the range from 0.055 dН to 0.11 dН, and the other - in the range from 0.015 dН to 0.025 dН, where dН is the outer diameter of the screw.