RU2509923C1 - Vertical chemical electrically driven pump with exposed impeller and method of transfer of chemically aggressive fluids - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: proposed pump unit comprises rotary motor, adaptor with power coupling and rotary semi-submersible pump. Composite pump housing comprises running section housing arranged above thrust plate and suspension case secured to thrust plate from below and locked with flow section housing. Said shaft runs in running section housing bearings and while its lower support extends through suspension case and into flow section housing to be rigidly coupled with impeller hub. Rotor shaft top end is fitted in adapter power coupling. Impeller comprises the main and cover discs with s set of curved vanes. Active volume of intervane channel filling allows forcing out in one impeller revolution of (5.0-1500)x10^-5 m³/rev of transferred medium. Impeller main disc is protected by impeller-like hydraulic lock. Flow section housing has circular ledged wall of wall outer radius smaller than that of impeller vanes.

EFFECT: simplified design, fabrication and assembly, higher reliability and efficiency.

22 cl, 4 dwg

Description

The invention relates to a pump engineering industry, and in particular, to designs of chemical vertical electric pump units with a centrifugal pump with an open impeller, intended for pumping chemically aggressive liquids, as well as to methods for pumping said liquids.

Known submersible centrifugal pump, which contains a spiral outlet, a curved diffuser and a rotary elbow. An impeller is installed in the bend on the shaft. The axis of the curved diffuser is bent to the axis of rotation of the impeller and passes without kinks into the middle line of the rotary knee, which in the projections of the longitudinal section of the rotary knee on the horizontal and vertical planes is clofoids (RU 2175732 C2, publ. 10.11.2001).

A centrifugal pump is known with a flowing part immersed in the pumped medium, comprising a motor, a shaft line formed by one or more suspensions, a flowing part formed by an impeller located in the pump casing and a branch. The upper part of the upper suspension is located above the level of the plate (RU 71711 U1, publ. 20.03.2008).

Known vertical chemical pump assembly containing a base plate with a motor vertically mounted on it and a centrifugal pump, in the suction pipe of which a booster screw is installed. The suction nozzle is made elongated with the possibility of mounting an electric pump unit above the level of the pumped medium. The screw is located in the lower part of the suction pipe and is fixed with a centrifugal wheel on a common elongated shaft (RU 83814 U1, publ. 06/20/2009).

Known submersible centrifugal pump for pumping aggressive liquids, containing an impeller mounted in the housing, mounted on the drive shaft of the electric motor by a screw connection with a protective cap. The flow part of the pump, including the impeller, is made of a material resistant to aggressive environments. The impeller is made in the form of a disk with radial holes and grooves of impellers on the lower and upper surface of the disk (RU 98498 U1, publ. 20.10.2010).

The disadvantages of the known technical solutions are the unwarranted reliability of the protection against leakage of chemically aggressive pumped liquid during prolonged operation of the pump during operation, the reduced pump life and insufficiently high efficiency of pumping working media with an increased concentration of aggressive components, which ultimately reduces the industry competitiveness of the pump and on their basis electric pump units.

The objective of the present invention is to develop a chemical vertical electric pump unit with a centrifugal pump, endowed with increased protection against leakage of chemically aggressive pumped liquid and atmospheric air pollution with toxic fumes and endowed with increased resource, reliability and efficiency of pumping these media, as well as in the development of a method for pumping chemically aggressive wednesday

The problem in terms of the electric pump unit is solved in that the chemical vertical electric pump unit with an open impeller, according to the invention, includes a pump with a housing, a support plate, a rotor with a shaft and an impeller in the form of an open-type multi-input impeller, a drive in the form of an electric motor with a housing and the rotor shaft, as well as an adapter with a power coupling, elastically connecting the shafts of the said rotors with the formation of a shaft line for transmitting torque to the impeller, while the adapter contains a power casing covering the said coupling along the circuit and connecting the pump and electric motor housings as a support, the pump is made of a centrifugal, vertical type, semi-submersible, preferably single-shell and at least one-stage with axial inlet and tangential or radial tap of the pumped medium, which is equipped with inlet and outlet pressure pipes, in addition, the pump housing is prefabricated and includes a chassis housing located above the base plate with at least two bearing supports, and also includes a suspension housing attached to the base plate from below, interlocked with the flow housing, the rotor shaft of the pump being double-mounted, installed in the bearings of the running gear housing and the lower console passed through the suspension housing with access to the flow passage housing, in which it is rigidly removably connected to the impeller hub, and the upper console of the rotor shaft is brought into the power coupling of the adapter, while the impeller contains a multi-input impeller, including the main di cc with a hub and with a system of curved blades fixed to the disk, optionally taken in the amount of (3 ÷ 24), preferably (5 ÷ 7) blades evenly separated by interscapular channels, the axes of which in the frontal projection are made of constant or variable curvature, with an average gradient the angle of installation of the axis of the scapula and the identical gradient of the angular configuration of the medial axis of the interscapular canal, optionally constituting rad / m on the length of the scapula (0 ÷ 7.0) with the possibility of expanding the range into the region of negative gradient values, active volume dynamically populate plurality interblade channels adapted variant providing the possibility to discharge flow per one rotation of the impeller (5,0 ÷ 500) × 10 ^-5 m ³ / on the pumping medium, wherein the main drive of the impeller is protected by the rear side of the impeller in the form of an odor trap formed by a system of luvoid blades, and the body of the flowing part is equipped with an annular removable back wall, step-like in cross section with the smaller of the external radii R _{min, art of} said wall, exceeding the radius of the blades and mpeller R _imp , which in this case is made sufficient to create a hydrodynamic protective backpressure against the pressure of the pumped medium penetrating the water seal during the operation of the pump.

In this case, an annular removable rear wall, stepwise cross-sectional, can be fulfilled satisfying each of the conditions by virtue of which the smaller of the external radii R _{min, the} said wall exceeds the radius of the impeller blades R _imp by ΔR

ΔR = R _{min, st} -R _imp ; ΔR> 0.5 h _{min, l} ;

where 0,5h h _{min, l} - half the minimum height of the blades on the output circuit of the impeller.

The impeller may contain from 5 to 15, preferably 12, lucid scapulae.

The mentioned radii of curvature of the axes of the blades and the medial axes of the interscapular channels in the frontal projection of the wheel can be twisted in the direction opposite to the rotation vector of the impeller and made outgoing from centers scattered around a conditional circle, the radius of which, in turn, is adopted, preferably, less than the radius of the disk the impeller, and the aforementioned removable rear wall of the housing of the flowing part is mounted in the aperture of the specified housing, having a bore radius, providing the possibility of input and output p the back wheel when mounting and removing the pump.

The pump rotor shaft can be supported on the chassis through said bearing bearings, one of which, preferably the lower one, contains a radial roller bearing, and the other, preferably the upper one, preferably two angular contact bearings, and in addition the bearing supports bearing lubrication system, for which grease fittings are made in the chassis housing.

The pump rotor shaft can be made up of sections with different diameters, while the section with the largest diameter is located in the altitude range between the aforementioned bearings, and the remaining sections of the shaft are made with diameters decreasing stepwise in the direction towards the shaft ends.

The interface between the chassis housing and the suspension housing in the area of the base plate may comprise an end, preferably a removable flange with stuffing box packing along the pump shaft.

The casing of the flow part of the pump may include the aforementioned rear step-like wall, the casing of the spiral collector made in compliance with the minimum differentiation of velocities at the inlet and outlet of the collector and equipped with an output pressure tangential or radial nozzle, as well as a cover with an inlet axial nozzle that together form a flow cavity with a volume sufficient to accommodate the impeller and the said spiral collector in communication with the discharge pipe, mainly tangentially, while mentioning the pressure pipe of the body of the flowing part is made diffuser with a difference in the areas of the inlet and outlet cross sections, which provides a decrease in the discharge flow rate at the outlet of the pipe by 1.1–4.2 times.

To eliminate leakage of the pumped medium along the shaft and through the connectors of the said housings, rubber o-rings, cuffs and seal assemblies can be installed, while at least one of the seal assemblies is made with stuffing box packing and is installed in the back wall of the pump body part from the side suspension bodies, in addition, at least one of these nodes is optionally performed with a labyrinth seal, also a slotted seal on the impeller is alternatively used in the pump.

The power coupling connecting the cantilever shaft of the electric motor rotor and the upper console of the pump rotor shaft facing it can be configured to transmit torque from the first to the second with damping mutual angular oscillations of these shafts, for which the power clutch is made in the form of two coupling halves rigidly connected each with one of the said rotor shafts and elastically connected to each other through a shock absorber, mainly in the form of a finger-sleeve-elastic ring insert type system with the number of bushes per hour Isla "fingers", but not less than two.

The flow part of the pump can optionally be equipped with an inlet pipe for directed supply of the fluid flow to the axial inlet of the impeller, and the discharge pipe of the pump is made with a flange for connecting to the discharge pipe, at least a portion of which is between the discharge pipe and the opening intended for passing the specified pipe in the base plate of the pump is made at an angle α = ~ π / 2, while the pressure line is equipped with flanges for connecting one of them to the flange of the pressure pipe, and the other, mainly, a removable flange for fixing the line in the base plate, while the said removable flange is equipped with an annular seal that prevents air from entering the pressure line.

The base plate can be made with at least two asymmetric eccentricities with respect to the center or axis of symmetry of the plate with openings, the diameter of one of which is made with the possibility of introducing into the opening at least a fixed support flange of the suspension housing, and the diameter of the other is optionally made larger than the outer diameter pressure line, at least the technologically necessary size of the outer diameter of the removable flange of the specified line, in addition, the base plate is equipped with sling loops or holes versions, as well as technological holes for fixed mounting of the electric pump unit to the design of the external tank, tank.

The adapter housing can be made, preferably, in a conical configuration and contains at least one process opening for servicing the power coupling.

The suspension housing can be equipped with a system of openings for communication with a variable volume of the pumped medium.

A chemical vertical electric pump unit with an open impeller can be designed for pumping chemically aggressive liquid media such as acids, alkalis, electrolytes and others with a temperature from 0 ÷ 98 ° C, with a hydrogen index of 0 ÷ 14 pH, density up to 1870 kg / m ³ , kinematic viscosity up to 30 × 10 ^-6 m ² / s and solid inclusions up to 1 mm with a volume concentration of the latter not exceeding 5%, or for pumping hot and crystallizing liquids with temperatures from 0 to 250 ° C.

The pump and the component motor can optionally be configured to supply from 12.5 to 315 m ³ / h and a pressure of from 20 to 90 m, while the electric motor is received with a variant power of 5 to 150 kW, adequate to the pressure and flow ranges and speed shaft preferably up to 1500 rpm, and with a shaft speed of preferably 2950 rpm, the electric pump unit is optionally configured to supply from 7.5 to 50 m ³ / h with a pressure of 20 to 90 m, power from 5 up to 350 kW.

The problem in terms of the pumping method is solved by the fact that in the method of pumping chemically aggressive liquids, according to the invention, the pumping is carried out in the process of production, transport, pumping or pumping from tanks, tanks or tanks for short-term or long-term storage of these liquids, using, for this, at least one chemical vertical electric pump assembly structurally described above.

In this case, a chemically aggressive liquid such as sulfuric acid solutions or a combination of two, including combinations of sulfuric and acetic acid, or three or more acids, including combinations of sulfuric, hydrochloric and nitric acid, with a concentration of from 0.1 to 98% and a temperature of 30 to 100 ° C, using chemically resistant coatings such as Teflon, applied at least to the parts of the pumping part in contact with the aggressive medium.

As the pumped medium can be used chemically aggressive fluid such as nitric acid, its solutions and / or components.

As the pumped medium, a chemically aggressive liquid such as phosphoric acid, its solutions and / or components with a concentration of from 1 to 90% and a temperature of from 20 to 100 ° C can be used.

As the pumped medium, a chemically aggressive liquid such as hydrochloric acid, its solutions and / or components with a concentration of from 0.2 to 37% and a temperature of from 20 to 60 ° C can be used.

As the pumped medium, a chemically aggressive liquid such as alkali with a concentration of from 5 to 97% and a temperature of from 15 to 135 ° C can be used.

The technical result achieved by the above set of features is to develop a chemical vertical electric pump unit with a centrifugal pump, endowed with increased protection against leakage of chemically aggressive pumped liquid and atmospheric air pollution with toxic fumes and endowed with increased resource, reliability and efficiency of pumping of these media, as well as development of a method for pumping chemically aggressive media.

This is achieved by the combination of the design solutions and technological parameters of the main components and assemblies developed in the invention, primarily the design of the open-type impeller system, the configuration of the blades and interscapular channels, the spiral collector and the pressure pipe, which together provide effective pumping of these environmentally hazardous environments. In addition, the technical result is achieved due to the design developed in the invention of the power coupling of the shafts of the rotors of the electric motor and pump, transmitting torque from the electric motor to the pump with vibration damping, and enhanced hydrodynamic protection during operation of the pump, optimally complemented by hydrostatic protection in the form of the system developed in the invention stuffing box, gap and labyrinth seals, as well as chemically resistant ring cuffs and gaskets from leaks of a chemically aggressive environment and toxic fumes during pumping during production, transport, pumping or pumping from tanks, tanks or tanks for short-term or long-term storage, including in closed production rooms, which eliminates the negative impact on the environment in all operational situations.

The invention is illustrated by drawings, where:

figure 1 shows a chemical vertical electric pump unit, a longitudinal section;

figure 2 - flow part of the pump, a longitudinal section;

figure 3 - base plate, top view (electric motor and power clutch are not shown);

figure 4 is a structural diagram of a power clutch, a longitudinal section.

The vertical chemical pump assembly includes a pump 1 with a housing 2, a base plate 3, a rotor with a shaft 4 and an impeller 5 in the form of an open-type multi-input impeller, a drive in the form of an electric motor 6 with a housing 7 and a rotor shaft 8, as well as an adapter 9 with a power coupling 10, elastically connecting the shafts 4 and 8 of the aforementioned rotors with the formation of the shaft for transmitting torque to the impeller 5.

The adapter 9 includes a power housing 11, covering the contour of the coupling 10 and connecting the housing 2 of the pump 1 and the housing 7 of the motor 6 as a support.

The pump 1 is made of a centrifugal, vertical type, semi-submersible, preferably single-shell and at least one-stage with an axial inlet and a tangential or radial outlet of the pumped medium, for which it is equipped with inlet and outlet pressure pipes 12 and 13, respectively.

The housing 2 of the pump 1 is prefabricated and includes a chassis 14 located above the base plate 3 with at least two bearing bearings 15, and also includes a suspension housing 16 attached to the base plate 3 from the bottom, interlocked with the body 17 of the flow part.

The shaft 4 of the rotor of the pump 1 is made of two-console, installed in the bearing bearings 15 of the chassis 14 of the chassis and the lower console 18 is passed through the chassis 16 of the suspension with access to the housing 17 of the flowing part, which is rigidly removably connected to the hub 19 of the impeller 5. The upper console 20 of the shaft 4 rotors inserted into the power coupling 10 of the adapter 9.

The impeller 5 contains a multiple-entry impeller, including a main disk 21 with a hub 19 and with a system of curved blades 22 mounted on the disk, optionally taken in the amount of (3 ÷ 24), preferably (5 ÷ 7) blades. The blades 22 are uniformly separated by interscapular channels, the axes of which in the frontal projection are made of constant or variable curvature, with an average gradient of the angle of installation of the axis of the scapula 22 and an identical gradient of the angular configuration of the medial axis of the interscapular canal, which is optionally equal to (0 ÷ 7.0) rad / m with the possibility of expanding the range in the region of negative gradient values. The active volume of the dynamic filling of the set of interscapular channels is made providing the option of ejecting onto the duct for one revolution of the impeller (5.0 ÷ 1500) × 10 ^-5 m ³ / about the pumped medium.

The main disk 21 of the impeller 5 is protected on the back by a water lock in the form of an impeller 23 formed by a system of luvoid blades.

The body 17 of the flowing part is provided with an annular removable rear wall 24, stepwise cross-sectional, with the smallest of the external radii R _{min, the} said wall exceeding the radius of the impeller blades R _imp , which is sufficient to create a hydrodynamic protective backpressure of the pressure of the pumped medium, penetrating into the water seal during the operation of the pump.

An annular removable rear wall 24, stepwise cross-sectional, is made satisfying each of the conditions by virtue of which the smaller of the external radii R _{min of the} said wall 24 exceeds the radius of the impeller blades R _{imp of the} main disk 21 of the impeller 5 by the value AR

ΔR = R _{min, st} -R _imp ; ΔR> 0.5h _{min, l} ,

where 0.5 h _{min, l} - half the minimum height of the blades 21 on the output circuit of the impeller 5.

Impeller 23 contains from 5 to 15, preferably 12, lucid scapulae.

The mentioned radii of curvature of the axes of the blades 22 and the medial axes of the interscapular channels in the frontal projection of the impeller 5 are twisted in the direction opposite to the rotation vector of the impeller 5 and are made outgoing from centers dispersed along a conditional circle, the radius of which, in turn, is preferably adopted less than the radius of the main disk 21 of the impeller 5. The removable rear wall 24 of the housing 17 of the flow part is mounted in the opening of the specified housing, having a through radius, providing input and output Static preparation wheels 5 during assembly and disassembly of the pump 1.

The shaft 4 of the pump rotor 1 is supported on the chassis 14 through the bearings 15. Preferably, the lower bearing comprises a roller bearing 25 and the other, preferably the upper bearing, preferably contains two angular contact bearings 26. Bearing bearings 15 equipped with a lubrication system of bearings 25, 26, for which a grease nipple 27 is made in the chassis housing 14.

The shaft 4 of the rotor of the pump 1 is made up of sections with different diameters. Section 28 with the largest diameter is located in the altitude range between the bearing supports 15. The remaining sections of the shaft 4 are made with diameters decreasing stepwise sequentially towards the ends of the shaft 4.

The interface unit of the chassis 14 of the chassis and the housing 16 of the suspension in the area of the base plate 3 contains an end, preferably a removable flange 29 with an oil seal 30 on the shaft 4 of the pump 1.

The housing 17 of the flow part of the pump 1 includes the aforementioned rear step-like wall 24, the housing 31 of the spiral collector, made in compliance with the minimum differentiation of velocities at the inlet and outlet of the collector and provided with an output pressure tangential or radial nozzle 13, as well as a cover 32 with an axial inlet 12, jointly forming a flow cavity 33 with a volume sufficient to accommodate the impeller 5 and the aforementioned spiral collector, in communication with the pressure pipe 13, mainly tangentially. The pressure pipe 13 of the housing 17 of the flow part is made diffuser with a difference in the areas of the input and output cross sections, which ensures a decrease in the speed of the pumped stream at the outlet of the pipe by 1.1–4.2 times.

To eliminate the leakage of the pumped medium along the shaft 4 of the pump 1 and through the connectors of the said housings 14, 16, 17 of the pump 1, rubber o-rings 34, cuffs and seal assemblies with stuffing box packing are installed. At least one seal assembly 35 is made with stuffing box packing 36 and is installed in the back wall 24 of the housing 17 of the pump flow part from the side of the suspension housing 16. At least one of the seal assemblies is optionally configured with a labyrinth seal (not shown in the drawings). Also, a slotted impeller seal (not shown in the drawings) is alternatively used in the pump.

A power coupling 10 connecting the cantilever shaft 8 of the rotor of the electric motor 6 and the upper console 20 of the shaft 4 of the rotor of the pump 1 facing it is configured to transmit torque from the first to the second with damping mutual angular oscillations of these shafts. Why power clutch 10 is made in the form of two coupling halves 37, 38, respectively, of the electric motor 6 and pump 1, each rigidly connected to the corresponding rotor shaft. The coupling halves 37, 38 are resiliently interconnected via a shock absorber 39, mainly in the form of a finger-sleeve-elastic ring insert type system with the number of bushings in terms of the number of fingers, but not less than two.

The flow part of the pump 1 is optionally equipped with an inlet pipe 40 for a directed supply of the fluid flow to the axial inlet of the impeller 5.

The pressure port 13 of the pump is made with a flange 41 for connecting to the pressure line 42. At least a portion of the pressure line 42 between the pressure pipe 13 and the passage 43 designed to pass the specified line in the base plate 3 of the pump is made at an angle α = ~ π / 2. The pressure line 42 is provided with flanges for connecting one of the flanges 44 to the flange 41 of the pressure pipe 13, and the other, mainly a removable flange 45 for fixing the line 42 in the base plate 3. The removable flange 45 is provided with an annular seal 46, which prevents air from entering the pressure line 42 .

The base plate 3 is made with at least two asymmetric with an eccentricity relative to the center or axis of symmetry of the plate with openings 43, 47. The diameter of the opening 47 is made with the possibility of introducing into it at least a fixed support flange 48 of the suspension housing 16. The diameter of the other opening is optionally made larger than the external diameter of the pressure line 42 by at least the technologically necessary external diameter of the removable flange 45 of the pipe 42. The base plate 3 is provided with sling loops or holes 49, as well as technological holes 50 for fixed mounting of the electric pump unit to design of external capacity, tank.

The housing 11 of the adapter 9 is preferably made in a conical configuration and contains at least one process opening 51 for servicing the power coupling 10.

The housing 16 of the suspension is equipped with a system of holes 52 for communication with a variable volume of the pumped medium.

The vertical chemical pump unit is designed for pumping chemically aggressive liquid media such as acids, alkalis, electrolytes and others with a temperature of 0 ÷ 98 ° C, with a hydrogen index of 0 ÷ 14 pH, density up to 1870 kg / m ³ , kinematic viscosity up to 30 × 10 ^-6 m ² / s and solid inclusions up to 1 mm with a volume concentration of the latter not exceeding 5%, or for pumping hot and crystallizing liquids with temperatures from 0 to 250 ° C.

The pump 1 and the completing electric motor 6 are alternatively configured to supply from 12.5 to 315 m ³ / h and a pressure of from 20 to 90 m, while the electric motor is received with a variant power from 5 to 150 kW, adequate to the pressure and supply ranges and speed shaft preferably up to 1500 rpm, and with a shaft speed of preferably 2950 rpm, the electric pump unit is optionally configured to supply from 7.5 to 50 m ³ / h with a pressure of 20 to 90 m, power from 5 up to 350 kW.

In a method for pumping chemically aggressive liquids, pumping is carried out during production, transport, pumping or pumping from tanks, tanks or reservoirs for short-term or long-term storage of said liquids, using at least one chemical vertical electric pump unit described above.

As the pumped medium, a chemically aggressive liquid such as sulfuric acid solutions or a combination of two, including combinations of sulfuric and acetic acid, or three or more acids, including combinations of sulfuric, hydrochloric and nitric acid, with a concentration of from 0.1 to 98% and temperature from 30 to 100 ° C, using chemically resistant coatings such as Teflon, applied at least to the parts of the pumping part in contact with the aggressive medium.

As the pumped medium, a chemically aggressive liquid such as nitric acid, its solutions and / or components is used.

As the pumped medium, a chemically aggressive liquid such as phosphoric acid, its solutions and / or components with a concentration of from 1 to 90% and a temperature of from 20 to 100 ° C is used.

As the pumped medium, a chemically aggressive liquid such as hydrochloric acid, its solutions and / or components with a concentration of from 0.2 to 37% and a temperature of from 20 to 60 ° C is used.

As the pumped medium, a chemically aggressive liquid such as alkali with a concentration of from 5 to 97% and a temperature of from 15 to 135 ° C is used.

The pumping of chemically aggressive liquids by the proposed chemical vertical electric pump unit is as follows.

Lower the unit into the tank with the pumped liquid and control the level height of the flooded part of the unit. Close the valve on the pressure pipe. Start the electric motor. Open the valve on the pressure line.

The chemically aggressive liquid medium pumped through the inlet supply pipe 12, entering the input of the rotating centrifugal impeller 5, moves from the center to the periphery under the action of centrifugal forces and diffuse expansion in the interscapular channels of the impeller 5, while acquiring kinetic energy and getting a swirl in the direction impeller rotation 5.

After exiting the impeller 5, the flow passes to a diffuser spiral collector, expanding to the discharge pipe 13 in a mode close to observing the equality of flow velocities throughout the collector. From the collection, the pumped medium enters the discharge pipe 13, made diffuser with a decrease in speed when passing through the pipe in half with the simultaneous transition of part of the kinetic energy of the flow to potential and enters the pressure pipe 42.

At the same time, during the operation of the unit, the stuffing box seal 35 protects against leakage of the pumped medium along the shaft 4 of the pump 1, and protects the packing 29 from leakage of the pumped medium into the pump chassis and through it to the atmosphere. The connectors of the housings 14, 16, 17 are sealed with rubber O-rings 34.

The unit is stopped in the following order: the valve on the pressure pipe is smoothly closed, the electric motor is turned off.

In this case, pumping is carried out during production, transport, pumping or pumping from tanks, tanks or reservoirs for short-term or long-term storage of these liquids. As the pumped medium, solutions of sulfuric acid or a combination of two, including a combination of sulfuric and acetic acid, are used; or nitric acid, its solutions and / or components; or phosphoric acid, its solutions and / or components with a concentration of from 1 to 90% and a temperature of from 20 to 100 ° C; or hydrochloric acid, its solutions and / or components with a concentration of from 0.2 to 37% and a temperature of from 20 to 60 ° C; or a liquid such as alkali with a concentration of 5 to 97% and a temperature of 15 to 135 ° C.

Thus, due to the design solutions and technological parameters developed in the invention for the main components and components of the pump as part of an electric pump unit, they achieve increased protection against leakage of chemically aggressive pumped liquid and, as a result, reduced atmospheric air pollution by toxic fumes, as well as increased durability and reliability unit operation and pumping efficiency of chemically aggressive liquid media.

Claims (22)

1. A vertical vertical electric pump assembly with an open impeller, characterized in that it includes a pump with a casing, a base plate, a rotor with a shaft and an impeller in the form of an open-type multi-input impeller, an electric motor drive with a casing and a rotor shaft, and an adapter with a power coupling elastically connecting the shafts of the said rotors with the formation of a shaft for transmitting torque to the impeller, the adapter includes a power housing covering the circuit of the coupling and as a support connecting the pump housing and the motor, the pump is made of a centrifugal, vertical type, semi-submersible, preferably single-shell and at least one-stage with axial inlet and tangential or radial outlet of the pumped medium, for which it is equipped with inlet and outlet pressure pipes, except moreover, the pump housing is prefabricated and includes a chassis housing located above the base plate with at least two bearing bearings, and also contains attached to the support on the bottom plate of the suspension housing, interlocked with the housing of the flowing part, the rotor shaft of the pump being double-mounted, installed in the bearings of the chassis of the chassis and the lower console passing through the housing of the suspension with access to the housing of the flowing part, in which it is rigidly removably connected to the impeller hub, and the upper console of the rotor shaft is brought into the power coupling of the adapter, while the impeller contains a multi-input impeller, including a main disk with a hub and a curvilinear system mounted on the disk x blades, optionally taken in the amount of (3 ÷ 24), preferably (5 ÷ 7), blades uniformly separated by interscapular channels, the axes of which in the frontal projection are made of constant or variable curvature, with an average gradient of the angle of installation of the axis of the blade and an identical gradient of the angular configuration the medial axis of the interscapular canal, optionally comprising on the blade length (0 ÷ 7.0) rad / m and with the possibility of expanding the range into the region of negative gradient values, and the active volume of the dynamic filling of the aggregate of inter the casing channels are designed to provide the option of ejecting onto the duct per revolution of the impeller (5.0 ÷ 1500) · 10 ^-5 m ³ / revolving medium, the main impeller disk being protected from the back by a water seal in the form of an impeller formed by an x-ray system and the body of the flowing part is equipped with an annular removable back wall that is cone-shaped in cross section with the smaller of the external radii R _{min, the} said wall, exceeding the radius of the impeller blades R _imp , which is thus made sufficient for Buildings of hydrodynamic protective backpressure to the pressure of the pumped medium penetrating the water seal during the operation of the pump. 2. The chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that the annular removable rear wall, stepwise cross-sectional, is made satisfying each of the conditions by virtue of which the smaller of the external radii R _{min, the} said wall exceeds the radius of the impeller blades R _imp the value of ΔR
ΔR = R _{min, st} -R _imp ; ΔR> 0.5h _{min, l} ,
where 0.5 h _{min, l} - half the minimum height of the blades on the output circuit of the impeller. 3. The chemical vertical electric pump unit with an impeller of the open type according to claim 1, characterized in that the impeller contains from 5 to 15, preferably 12, lumbar blades. 4. The vertical vertical electric pump unit with an impeller according to claim 1, characterized in that the said radii of curvature of the axes of the blades and the medial axes of the interscapular channels in the frontal projection of the wheel are twisted in the direction opposite to the rotation vector of the impeller, and are made outgoing from the centers, dispersed around a conditional circle, the radius of which, in turn, is adopted, preferably, less than the radius of the impeller disk, the aforementioned removable rear wall of the body of the flowing part mounted ana aperture in said body having an entrance radius, providing the possibility impeller input and output during assembly and disassembly of the pump. 5. A vertical vertical electric pump assembly with an impeller according to claim 1, characterized in that the pump rotor shaft is supported on the chassis through said bearing bearings, one of which, preferably lower, contains a radial roller bearing and the other preferably the upper one contains, preferably two angular contact bearings, and, moreover, the bearing supports are provided with a lubrication system for bearings, for which purpose grease nipples are made. 6. A chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that the pump rotor shaft is made up of sections with different diameters, while the section with the largest diameter is located in the altitude range between the said bearing bearings, and the remaining sections of the shaft made with diameters gradually decreasing sequentially towards the ends of the shaft. 7. The vertical vertical electric pump unit with an impeller according to claim 1, characterized in that the interface unit of the chassis and suspension housing in the area of the base plate comprises an end, preferably a removable flange with stuffing box packing along the pump shaft. 8. The chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that the casing of the flowing part of the pump includes the said rear step-like wall, the casing of the spiral collector, made in compliance with the minimum differentiation of speeds at the inlet and outlet of the collector and equipped with an outlet pressure head a tangential or radial nozzle, as well as a cover with an axial inlet nozzle, together forming a flow cavity with a volume sufficient to accommodate the impeller, and is mentioned about the spiral collector in communication with the pressure pipe, mainly tangentially, while the pressure pipe of the body of the flowing part is made diffuser with a difference in the area of the input and output cross sections, which provides a decrease in the discharge flow rate at the outlet of the pipe by 1.1 ÷ 4.2 times . 9. A vertical vertical electric pump assembly with an impeller according to claim 1, characterized in that rubber o-rings, cuffs and seal assemblies are installed to eliminate leakage of the pumped medium along the shaft and through the connectors of the said housings, at least one of the seal assemblies is made with stuffing box packing and is installed in the back wall of the pump body part from the side of the suspension body, in addition, at least one of these nodes is optionally made with a labyrinth seal m, and the pump is used alternatively with a gap seal on the impeller. 10. The chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that the power coupling connecting the cantilever shaft of the electric motor rotor and the upper console of the pump rotor shaft facing it is configured to transmit torque from the first to the second with damping mutual angular vibrations of these shafts, for which the power clutch is made in the form of two coupling halves, each rigidly connected to one of the said rotor shafts and elastically connected to each other through a shock absorber, eimuschestvenno, in a system such as "finger-sleeve-resilient annular liner" with the number of sleeves in the number of "fingers", but at least two. 11. The chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that the flow part of the pump is optionally equipped with an inlet pipe for directional inlet of the pumped medium flow into the axial inlet of the impeller, and the pump discharge port is made with a flange for connecting to the pressure head at least a section between the pressure pipe and the passage intended for passing through the pipe in the base plate of the pump is made at an angle α = ~ π / 2, and the pressure pipe ene flanges for attaching them to one of flange discharge nozzle and the other mainly detachable flange for fixing the pipe in the base plate, wherein said removable flange is provided with a sealing ring, which prevents air from entering the pressure line. 12. A vertical vertical electric pump assembly with an impeller according to claim 11, characterized in that the base plate is made with at least two asymmetric eccentricities relative to the center or axis of symmetry of the plate with openings, the diameter of one of which is made with the possibility of entering into the opening, at least a non-removable support flange of the suspension housing, and the diameter of the other variant is made to exceed the external diameter of the pressure line by at least a technologically necessary value of the external diameter volume flange of the specified line, in addition, the base plate is equipped with sling loops or holes, as well as technological holes for fixed mounting of the pump unit to the design of the external tank, tank. 13. The chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that the adapter housing is preferably made in a conical configuration and contains at least one technological opening for servicing the power coupling. 14. The chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that the suspension housing is equipped with a system of openings for communication with a variable volume of the pumped medium. 15. The chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that it is intended for pumping chemically aggressive liquid media such as acids, alkalis, electrolytes and others with a temperature of 0 ÷ 98 ° C, with a hydrogen index of 0 ÷ 14 pH, density up to 1870 kg / m ³ , kinematic viscosity up to 30 · 10 ^-6 m ² / s and solid inclusions up to 1 mm with a volume concentration of the latter not exceeding 5%, or for pumping hot and crystallizing liquids with temperatures from 0 to 250 ° C. 16. The chemical vertical electric pump unit with an open impeller according to claim 1, characterized in that the pump and the completing electric motor are optionally configured to supply from 12.5 to 315 m ³ / h and a pressure of from 20 to 90 m, while the electric motor take with a variant power from 5 to 150 kW, adequate to the pressure and supply ranges and shaft speeds, preferably up to 1500 rpm, and at a shaft speed, preferably up to 2950 rpm, the electric pump unit is alternatively configured to supply from 7.5 to 50 m ³ / h with pressure ohm from 20 to 90 m, power from 5 to 350 kW. 17. A method of pumping chemically aggressive liquids, characterized in that the pumping is carried out during production, transport, pumping or pumping from tanks, tanks or reservoirs for short-term or long-term storage of these liquids, using at least one vertical chemical pump unit which is made according to any one of claims 1 to 16. 18. The method for pumping chemically aggressive liquids according to claim 17, characterized in that as the pumped medium, a chemically aggressive liquid such as sulfuric acid solutions or a combination of two, including a combination of sulfuric and acetic acid, or three or more acids, including a combination of sulfuric hydrochloric acid and nitric acid, with a concentration of from 0.1 to 98% and a temperature of from 30 to 100 ° C, using chemically resistant coatings such as Teflon, applied at least to parts of the flowing part in contact with an aggressive medium Sosa. 19. The method of pumping chemically aggressive liquids according to claim 17, characterized in that a chemically aggressive liquid such as nitric acid, its solutions and / or components is used as the pumped medium. 20. The method for pumping chemically aggressive liquids according to claim 17, characterized in that a chemically aggressive liquid such as phosphoric acid, its solutions and / or components with a concentration of from 1 to 90% and a temperature of from 20 to 100 ° C is used as the pumped medium. 21. The method for pumping chemically aggressive liquids according to claim 17, characterized in that a chemically aggressive liquid such as hydrochloric acid, its solutions and / or components with a concentration of 0.2 to 37% and a temperature of 20 to 60 ° is used as the pumped medium. C. 22. The method for pumping chemically aggressive liquids according to claim 17, characterized in that a chemically aggressive liquid such as alkali with a concentration of from 5 to 97% and a temperature of from 15 to 135 ° C is used as the pumped medium.

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