RU2509921C1 - Horizontal chemical pump with exposed impeller - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: proposed pump comprises running and flow sections. Flow section housing comprises header case with circular ledged comb, rear wall consisting of connected circular comb of header case and rear wall ledged circular element as well as detachable cover. Pump running part housing is equipped with bearings and crankcase. Exposed impeller is composed of multistart impeller including vaned main disc with hub and circular comb. Aid comb features outer radius congruent with mating inner radius of circular ledged comb in header case. Said main disc is equipped with hydrodynamic protection composed by impeller. Protection is furnished with hydraulic lock with extra impeller with radius smaller than that of working impeller. Circular element of rear wall geometrically complies by inner radius of ledge with hydraulic lock radius.

EFFECT: better tightness, longer life and higher reliability.

11 cl, 2 dwg

Description

The invention relates to pump engineering, and in particular to structures of horizontal chemical centrifugal pumps with an impeller of the open type, designed for pumping chemically aggressive liquids.

Known sealed centrifugal pump containing a housing with an impeller placed in it, driven into rotation by a cylindrical magnetic coupling, the leading coupling of which is connected to the drive shaft of the electric motor, and driven - with the impeller. The coupling halves are installed coaxially, separated by a screen in the form of a cylindrical cup. The glass is made with a variable wall thickness along its generatrix, and the section of the smallest wall thickness is located between the poles of the leading and driven half-couplings (RU 2088807 C1, publ. 08.27.1997).

The closest in essence and achieved technical result is known to a centrifugal pump, comprising a housing made of wear-resistant material fixed to the bed, having an inlet and discharge nozzles with flanges, a shaft with a closed impeller in bearing bearings and a seal assembly. At the inlet and discharge nozzles, the flanges are made rotating, removable and mounted on the nozzles without direct stop of the flange in the nozzle. Semicircular recesses are made on the flange and nozzles, in which split circular retaining rings are placed, which absorb axial loads at the joints of the flanges and nozzles (RU 2332591 C1, publ. 08.28.2008).

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, which results in insufficient pump life and the efficiency of pumping working fluids with an increased concentration of aggressive components and, ultimately, reduces the industry competitiveness of the pump and performed on their basis electric pump units.

The objective of the present invention is to develop a horizontal chemical pump, endowed with increased protection against leakage of chemically aggressive pumped liquid and atmospheric air pollution by toxic fumes, as well as endowed with increased resource, reliability and efficiency of pumping chemically aggressive liquid media.

The problem is solved in that the chemical horizontal pump, according to the invention, is made centrifugal, at least one-stage, cantilever type, has a rotor with a shaft and an impeller of the open type, contains a housing consisting of a chassis of the chassis and the housing of the flowing part, while the latter includes a spiral collector case combined with a pressure pipe with an annular ledge-shaped ridge, a back wall consisting of a conjugated annular ridge of the collector body and a ledge-shaped annular element and the back wall, as well as a removable inlet cover made with the axial inlet pipe jointly forming a flow cavity, and the pump chassis housing is equipped with a crankcase and at least two angular contact and radial bearing bearings and is made covering, mainly, most of the rotor shaft length moreover, the rotor shaft of the pump is made with consoles, while the length of one of them, equipped with an impeller, is made not less than two times the length of the other console, and the open impeller is made in the form of a multiple-entry impeller, including a main disk equipped with a system of blades with a hub and along the contour of an annular ridge facing the opposite to the impeller, the ridge being made with an external radius congruent with the corresponding internal radius of the annular ledge-like ridge in the collector body, with the main disk between the specified crest and hub is endowed with hydrodynamic protection in the form of an impeller-forming system of x-ray blades, and in addition, the hydrodynamic protection is enhanced by water trap rum in the form of an additional autonomous disk mounted on the shaft, also equipped with an impeller with a system of luvoid blades, at least from the side opposite to the impeller, and the radius of the impeller is less than the impeller radius by an amount sufficient to create a hydrodynamic protective backpressure of the pumped medium penetrating into the hydraulic lock wherein said step-shaped annular element of the back wall of the body of the flow part is geometrically aligned with the inner radius of the step with the radius of the guide ozatvora furthermore smaller external radius of said removable cover is made not less than the radius of the through runner with providing input and output capabilities of the last running of the cavity during assembly and disassembly of the pump.

In this case, the pump impeller may comprise a multi-start curved system attached to the main disk, at least in a projection onto the conditional plane of the main disk of the blades separated by interscapular channels, the impeller blades being made of the same or different length, and the number of impeller blades is taken from 3 up to 24, preferably from 5 to 7, while the active volume of dynamic filling of the set of interscapular canals includes a variant possibility of discharge into the duct per revolution a wheel (5 ÷ 1500) × 10 ^-5 m ³ / of the pumped fluid.

The pressure pipe of the body of the flowing part can be made in the form of a 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 diffuser by 1.2–4.0 times.

The impeller hub can be made with at least one external step for congruent pairing in the step zone with a step-like annular element of the back wall of the flow part housing with the possibility of free rotation of the shaft with the impeller hub.

The inlet pipe, the flow cavity, the collector and the pressure pipe can be placed sequentially in the pump body of the pump with the formation of a single channel along the flow of the pumped medium, in which the inlet pipe is symmetrical about the axis of the shaft and contains a feed neck with a radius partially overlapping in the projection onto the conditional the plane normal to the axis of the shaft, the ends of the blades facing the specified axis, in addition, the flow cavity is made with the back, side and inlet walls forming the volume sufficient to accommodate the impeller and the spiral collector, which is made mainly tangentially in communication with the discharge pipe.

The pump rotor shaft may be supported on the chassis housing through said bearing bearings, one of which, preferably facing the flow housing, comprises a radial bearing, and the other, preferably facing the electric motor, preferably comprises a double angular contact bearing.

The pump rotor shaft may comprise an stuffing box assembly, including a packing housing, as well as a stuffing box consisting of rings, a drain sleeve, coolant inlet and outlet fittings, and preferably a split flange, while when the pump is running, coolant enters the seal assembly through the lower the fitting, and the outlet is carried out through the upper fitting.

To eliminate leakage of the pumped fluid along the shaft and through the connectors of the housings of the flowing and running parts, sealing rings can be installed, preferably of an elastic material such as rubber.

The side wall of the pump’s flow cavity can form a spiral collector, which, outside the impeller contour, has the shape of a biconvex shell twisted in a spiral moving sequentially with increasing radius in the conventional midplane and at least in one section of the cross section convexly curved in the conventional plane normal to the aforementioned the middle plane of the collector and drawn through the axis of the shaft of the pump rotor, while this shell is provided at the outlet with an opening in communication with the flow from the tangent the pressure nozzle of the casing of the flowing part of the pump adjacent to it.

A horizontal chemical pump can be used 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, as well as fire and explosion hazardous media, while the pump for pumping the aforementioned hot and christ llizuyuschihsya media system is provided with heating and cooling flow part bearing assemblies.

The chemical horizontal pump can be made with the possibility of power connection with an electric motor, mainly asynchronous for using the latter as a drive of the pump rotor shaft, providing a shaft speed transmitted to the impeller, preferably up to 1500 rpm and with a power rating from 8 to 435 kW with the possibility of using electric motors with a shaft speed of up to 3000 rpm and a variant power from 7.5 to 250 kW.

The technical result achieved by the above set of features consists in the development of a horizontal chemical pump with an open impeller, endowed with increased protection against leakage of chemically aggressive pumped liquid, as well as increased resource, reliability and efficiency of pumping working fluids. This is achieved by a combination of the design solutions and technological parameters of the main components and elements of the pump developed in the invention, first of all, the combined system of enhanced hydrodynamic protection during the operation of the pump, optimally complemented by hydrostatic protection from leaks of chemically aggressive media and toxic fumes, which eliminates the negative effect on bearing supports and the environment in all operational situations. In addition, the technical result is achieved due to the design solution developed in the invention and the shape of an open type impeller, a spiral collector and a pressure pipe, which together provide effective pumping of these environmentally hazardous media.

The technical result is also expressed in increased wear resistance to chemical and mechanical aggression of the most wearing parts of the flowing part of the proposed pump design, in particular, due to the design of the hydraulic shutter developed in the invention in combination with the parking hydraulic protection system of the pump and the coupling of the moving parts of the rotor with the body of the flowing and running parts of the pump .

The invention is illustrated by drawings, where:

figure 1 shows a centrifugal pump, a longitudinal section;

figure 2 - impeller, section.

The chemical horizontal pump is made centrifugal, at least one-stage, cantilever type, has a rotor with a shaft 1 and an impeller 2 open type. The pump comprises a housing consisting of a housing 3 of the running gear 4 and a housing 5 of the flowing part 6. The housing 5 of the flowing part 6 includes a housing 8 of a spiral collector with an annular step-like ridge 9, a rear wall consisting of a conjugated annular ridge 9 of the housing 8 the collector and the ledge-like annular element 10 of the back wall, as well as a removable inlet cover 12 made with the inlet axial pipe 11, together forming a flow cavity 13.

The housing 3 of the running gear 4 of the pump is equipped with a crankcase 14 and at least two angular contact and radial bearing bearings 15 and 16, respectively, and is made covering mainly most of the length of the shaft 1 of the rotor. The shaft 1 of the pump rotor is made with consoles 17. The length of the console, equipped with an impeller 2, is made not less than twice the length of the other console.

The impeller 2 of the open type is made in the form of a multi-impeller, including a main disk 19 equipped with a system of blades 18 with a hub 20 and along the contour of an annular ridge 21 facing the side opposite to the impeller. The ridge 21 is made with an outer radius congruent with the mating inner radius of the annular ledge-like ridge 9 in the housing 8 of the collection. The main disk 19 between the crest 21 and the hub 20 is endowed with hydrodynamic protection in the form of an impeller system 22 of the x-ray blades. The hydrodynamic protection is reinforced by a water lock 23 in the form of an additional self-contained disk mounted on the shaft 1, also equipped with an impeller 24 with a system of x-ray vanes, at least from the side opposite to the impeller. The radius of the impeller 24 is made smaller than the radius of the impeller 2 by an amount sufficient to create a hydrodynamic protective backpressure of the pumped medium penetrating into the hydraulic lock 22.

The said step-like annular element 10 of the back wall of the housing 5 of the flow part 6 is geometrically aligned with the inner radius of the step with the radius of the valve 23.

The smaller of the outer radii of the removable cover 12 is made not less than the passage radius of the impeller 2 with the possibility of input and output of the latter from the flow cavity 13 during installation and dismantling of the pump.

The impeller 2 of the pump comprises a multi-start curved system attached to the main disk 19, at least in projection onto the conditional plane of the main disk 19 of the blades 18, separated by interscapular channels. The blades 18 of the impeller 2 are made of the same or different lengths, and the number of blades 18 of the impeller is taken from 3 to 24, preferably from 5 to 7. The active volume of dynamic filling of the set of interscapular channels includes the option of discharge into the duct during one revolution of the impeller (5 ÷ 500) × 10 ^-5 m / rev fluid pumped.

The pressure pipe 7 of the housing 5 of the flow part 6 is made in the form of a diffuser with a difference in the area of the input and output cross sections, which ensures a decrease in the speed of the pumped stream at the outlet of the diffuser by 1.2 ÷ 4.0 times.

The hub 20 of the impeller 2 is made with at least one external ledge 25 for congruent pairing in the step zone with the ledge-like ring element 10 of the back wall of the housing 5 of the flow part 6 with the possibility of free rotation of the shaft 1 with the hub 20 of the impeller 2.

The inlet pipe 11, the flow cavity 13, the collector and the pressure pipe 7 are placed in the housing 5 of the flow part 6 of the pump in series with the formation of a single channel along the flow of the pumped medium. The inlet pipe 11 is symmetrical about the axis of the shaft 1 and contains a throat with a radius partially overlapping in the projection onto a conditional plane normal to the axis of the shaft 1, the ends of the blades 18 facing the specified axis. The flow cavity 13 is made with the back, side and inlet walls, forming a volume sufficient to accommodate the impeller 2 and the spiral collector, which is made mainly tangentially communicated with the discharge pipe 7.

The shaft 1 of the pump rotor is supported on the housing 3 of the running gear 4 through the aforementioned bearing bearings 15, 16. The bearing support 16 facing the housing 5 of the flowing part contains a radial, mainly roller bearing 26. The bearing support 15 contains mainly a double angular contact bearing 27.

The shaft 1 of the pump rotor contains a packing assembly, including a packing housing 28, as well as a packing stuffing 29 consisting of rings, a drain sleeve 30, coolant inlet and outlet fittings, and preferably a split flange 31. When the unit is running, coolant flows into the packing assembly through the lower fitting 32, and the outlet is carried out through the upper fitting.

To eliminate the leakage of the pumped liquid along the shaft 1 and through the connectors of the housings 3 and 5, respectively, of the running and flowing parts, sealing rings 33 are installed, preferably of an elastic material such as rubber.

The side wall of the flow cavity 13 of the pump forms a spiral collector. The collection outside the impeller 2 contour has the shape of a biconvex shell twisted in a spiral, successively increasing radius, moving in the conditional midplane and convexly curved in at least one section of the cross section in the conditional plane normal to the said midplane of the collector and drawn through the shaft axis 1 pump rotor. The specified shell is provided at the outlet with an aperture in fluid communication with the pressure nozzle 7 of the housing 5 of the flow passage 6 of the pump tangentially adjacent to it.

A horizontal chemical pump is designed for pumping chemically aggressive liquid media such as acids, alkalis, electrolytes and others with a temperature of 0 ÷ 98 ° C, with a pH 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, as well as fire and explosion hazardous environments. The pump for pumping the aforementioned hot and crystallizing media is equipped with a heating system for the flow part and cooling of the bearing assemblies.

The chemical horizontal pump is made with the possibility of power connection with an electric motor, mainly asynchronous for using the latter as a drive of the pump rotor shaft, providing a shaft speed transmitted to the impeller, preferably up to 1500 rpm and with an option power of 8 to 435 kW with the possibility the use of electric motors with a shaft speed of up to 3000 rpm and a variant power of 7.5 to 250 kW.

The work of the proposed pump is as follows.

The pumped liquid medium through the inlet pipe 11, entering the input of the rotating centrifugal impeller 2, moves from the center to the periphery under the action of centrifugal forces and diffuse expansion in the interscapular channels of the impeller 2, while acquiring kinetic energy and getting a twist in the direction of rotation of the impeller 2.

After exiting the impeller 2, the flow passes to a diffuser spiral collector, expanding to the discharge pipe 7 in a mode close to observing the equality of flow velocities throughout the collector. From the collection, the pumped liquid enters the discharge pipe 7, made diffuser with a decrease in speed when passing through the pipe in half with the simultaneous transfer of part of the kinetic energy of the flow to the potential and enters the pressure pipe. At the same time, the running part of the pump during operation protects against leakage of the pumped liquid into the partially open running gear 4 and through it into the atmosphere a hydrodynamic protection in the form of a water lock 23 with a rotating disk with an impeller 24, which creates back pressure and keeps the pump shaft 1 dry. And after the end of the pump and finding it with a fixed position of the rotor, the pump is protected by stuffing box 29.

Thus, due to the design solutions and technological parameters of the main components and elements of the pump developed in the invention, 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, reliability of the pump and pumping efficiency chemically aggressive liquid media.

Claims (11)

1. A horizontal chemical pump, characterized in that it is made of centrifugal, at least one-stage, cantilever type, has a rotor with a shaft and an impeller of an open type, contains a housing consisting of a chassis and a flow housing, the latter includes a combined with a pressure nozzle, the casing of the spiral collector with an annular ledge-shaped ridge, the rear wall, consisting of the conjugated annular ridge of the collector housing and the ledge-shaped annular element of the back wall, as well as removable an inlet cover made with an axial inlet pipe jointly forming a flow cavity, and the chassis of the pump running gear is provided with a crankcase and at least two angular contact and radial bearing supports and is designed to cover mainly the greater part of the rotor shaft length, and the pump rotor shaft is made with consoles, while the length of one of them, equipped with an impeller, is made not less than twice the length of the other console, and the impeller of the open type is made in the form of a multi-impeller and including a main disk equipped with a system of blades with a hub and along the contour of an annular ridge facing in the direction opposite to the impeller, said ridge being made with an outer radius congruent with the reciprocal inner radius of an annular ledge-like ridge in the collector body, while the main disk is between the ridge and the hub is endowed with hydrodynamic protection in the form of an impeller-forming system of x-ray blades and, in addition, the hydrodynamic protection is reinforced with a water seal in the form of a mounted on the additional autonomous disk, also equipped with an impeller with a system of luvoid blades, at least from the side opposite to the impeller, and the radius of the impeller is made smaller than the radius of the impeller by an amount sufficient to create a hydrodynamic protective backpressure of the pumped medium penetrating into the hydraulic seal, while the said step-like the annular element of the back wall of the body of the flowing part is geometrically consistent with the inner radius of the step with the radius of the hydraulic seal, in addition, a smaller and External radii of said removable cover is made not less than the radius of the through runner with providing input and output capabilities of the last running of the cavity during assembly and disassembly of the pump. 2. The chemical horizontal pump according to claim 1, characterized in that the impeller of the pump comprises a multi-start system curved, at least in projection onto the conditional plane of the main disk of the blades, separated by interscapular channels, the impeller blades being the same or different lengths, and the number of impeller blades is taken from 3 to 24, preferably from 5 to 7, while the active volume of dynamic filling of the set of interscapular channels includes a variant the ejection rate per channel for one revolution of the impeller (5 ÷ 500) × 10 ^-5 m ³ / revolving fluid medium. 3. The chemical horizontal pump according to claim 1, characterized in that the discharge pipe of the body of the flowing part is made in the form of a diffuser with a difference in the area of the input and output cross sections, which ensures a decrease in the discharge flow rate at the outlet of the diffuser by 1.2 ÷ 4.0 times . 4. The horizontal chemical pump according to claim 1, characterized in that the impeller hub is made with at least one external step for congruent pairing in the step zone with a step-like ring element of the back wall of the flow part housing with the possibility of free rotation of the shaft with the impeller hub. 5. The chemical horizontal pump according to claim 1, characterized in that the inlet pipe, flow cavity, collector and pressure pipe are placed in the housing of the pump flow part in series with the formation of a single channel along the flow of the pumped medium, in which the inlet pipe is made symmetrical about the axis of the shaft and contains a throat with a radius partially overlapping in the projection onto a conventional plane normal to the axis of the shaft, the ends of the blades facing the specified axis, in addition, the flow cavity is made with t flax, and filar side walls defining a volume sufficient to accommodate the impeller and collector, which is made, preferably, tangentially communicating with the discharge port. 6. The chemical horizontal pump according to claim 1, characterized in that the pump rotor shaft is supported on the chassis housing through said bearing bearings, one of which, preferably facing the flow housing, contains a radial bearing, and the other, preferably facing the electric motor, mainly contains a double angular contact bearing. 7. The horizontal chemical pump according to claim 1, characterized in that the pump rotor shaft comprises a stuffing box assembly, including a packing housing, as well as a stuffing box consisting of rings, a drain sleeve, coolant supply and drain fittings, and preferably a split flange, in this case, when the pump is running, the coolant enters the seal assembly through the lower fitting, and the outlet is carried out through the upper fitting. 8. The chemical horizontal pump according to claim 1, characterized in that to eliminate leakage of the pumped fluid along the shaft and through the connectors of the housings of the flowing and running parts, sealing rings are installed, preferably of an elastic material such as rubber. 9. The horizontal chemical pump according to claim 5, characterized in that the side wall of the pump's flow cavity forms a spiral collector, which, outside the impeller contour, has the shape of a biconvex shell twisted in a spiral moving in a conditional middle plane with a successively increasing radius and not less than one section of the cross section is convexly curved in a conventional plane normal to the said middle plane of the collector and drawn through the axis of the shaft of the pump rotor, while the specified shell and the outlet opening, flow communication with the tangentially adjacent thereto running pressure port of the pump housing. 10. The chemical horizontal pump 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, and fire and explosion hazardous environments, while the pump for pumping mention s hot and crystallizing media provided with a heating system and the cooling flow part bearing assemblies. 11. The chemical horizontal pump according to claim 1, characterized in that it is made with the possibility of power connection with an electric motor, mainly asynchronous for using the latter as a drive shaft of the pump rotor with a shaft speed transmitted to the impeller, preferably up to 1500 rpm min and variant power from 8 to 435 kW with the possibility of using electric motors with a shaft speed of up to 3000 rpm and variant power from 7.5 to 250 kW.

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