RU2452878C1 - Heterogeneous medium transfer injector pump - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: pump comprises tubular feed and discharge branch pipes arranged in cylindrical casing to make annular clearance in axial direction and pressure chamber in radial direction, and branch pipe for tangential feed of induced fluid arranged inclined in casing. In compliance with this invention, additionally incorporated is swirler of induced fluid arranged in pressure chamber on feed tubular branch pipe made up of sleeve with through spiral channels exposed on its faces made on its outer surface. Outlet branch pipe represents Laval nozzle with confuser and diffuser sections with straight generating lines. Said confuser section is arranged in casing on thread to axially displace in annular clearance. Note here that opening angle of confuser section makes α₁=55-65°. Note here that relationship between inner diameters of end faces of outlet and inlet diameters d₁ and d₂ of branch pipes makes d₂/d₁=1.0-1.5.

EFFECT: ease of transfer ensured by centering solid particles tending to clogging.

4 cl, 5 dwg

Description

The invention relates to transportation by pipelines of heterogeneous media and can be used in industry, agriculture, construction, transport and other industries.

A well-known inkjet apparatus is a pump for transporting media including liquid, solid and gaseous components (RU 2262008, C1, 10.10.2005, Abiyev), the casing of which consists of a cylinder-conical shaped confuser, a neck and a diffuser, with a nozzle installed coaxially with the confuser in the form a cylindrical tube connected to the axial nozzle, the second nozzle is made tangentially to the confuser in its wide part, and the confuser has an opening angle of 10-40 °, and the diffuser has an opening angle of 4-30 °, the nozzle tip is made tapering, in the conical part of the confuser p found on the rear guide sleeve attached to it by means of blades, bent by swirling flow streamlines.

Known inkjet apparatus - a vortex ejector (SU 1333866 A1, 08/30/1987, Margulis and others), containing a swirl chamber with central passive and annular active nozzles, a swirl mounted on the active nozzle and made in the form of a screw thread placed at an angle of 8 14 °. Passive medium is sucked into the chamber when creating a vacuum in the swirl chamber. However, this device is optimized to provide better heat transfer.

Known ejector pump according to patent RU 2247873 C2, 03/10/2005, Khavkin and others (the closest analogue). The pump includes a housing, a nozzle for supplying an ejected fluid connected to a housing, a supply nozzle for supplying an ejected fluid, an annular nozzle connected to a nozzle for supplying an ejected fluid, a diffuser associated with the mixing chamber, and a pipe for discharging a mixture of ejected and ejected fluids. The inner diameter of the nozzle for supplying the ejected fluid is 0.15-0.32 of the inner diameter of the pipe for discharging the mixture of the ejecting and ejected fluids, the length of the mixing chamber is 3-6 times the working section of the annular nozzle, and the diffuser angle is 2-20 degrees.

However, when transporting liquid media of a heterogeneous composition, where the dimensions of individual inclusions can significantly exceed the bore of the pipelines (as well as the injection pump), the pump may become clogged and lose its working capacity.

For pipes with a cross-section of 40-60 mm with pumping by an injection pump, objects whose size in a tangled and saturated state exceeds the living section / diameter of the pipe are problematic. So, if a long object, for example a bandage with a small section in the straightened state, can be carried away by the flow and transported along with it to the collection tank along the drain line, then for a bandage coil this is a problem, because, depending on the size, it will essentially be a cork for the system. The applicant has shown the possibility of transporting bulk and lengthy products from textile and similar materials in a stream without siltation of pipelines. This is achieved by the features of the construction of the path and the design of the injection pump, which provides not only the creation of a larger specific pressure unit of the ejecting fluid transporting vacuum, but also the swirling flow. As a result, in addition to obtaining a larger suction pulse, the product curls when it passes through, moisture is squeezed out of it, respectively, its live section decreases and the product is transported along with the flow without difficulty. It should be noted that when the object passes through the field of twisting forces, the object is oriented along the pump axis, centered, and this reduces friction against the walls and contributes to its successful delivery to the collection tank. In addition, the forced twisting of the medium in combination with a higher suction force additionally contributes to the self-cleaning of the pipes, i.e. prevents the loss of operability of the transport system as a whole.

Patented injection pump for transporting a heterogeneous medium contains placed in a cylindrical housing with the formation of an annular gap in the axial direction and a pressure chamber in the radial direction of the tubular inlet and outlet nozzles and a nozzle installed in the housing for supplying an ejection fluid.

The difference between the pump is that an eductive fluid swirl is additionally introduced, which is installed in the pressure chamber on the inlet tubular pipe, made in the form of a sleeve, on the outer surface of which through spiral channels open at its ends are formed. The outlet pipe is made in the form of a Laval nozzle having a confuser and diffuser part with rectilinear generators. The confuser part is mounted in the housing on a thread with the possibility of axial movement in the annular gap. The opening angle of the confuser part is α ₁ = 55-65 °, the ratio of the length of the confuser L _K to the diffuser L _D parts in the axial direction is L _K / L _D = 0.22-1.1, and the ratio of the inner diameters of the output tip d ₂ and supply d ₁ nozzles - d ₂ / d ₁ = 1.0-1.5.

The device can be characterized in that through spiral channels are placed at an angle of 15-60 ° to the longitudinal axis of the sleeve.

The device can also be characterized by the fact that the inner diameter d _{1 of the} inlet pipe is d ₁ = (1.0-1.3) d _kp , where d _kp is the diameter of the critical section of the Laval nozzle of the inlet pipe, and that is installed at the tip of the outlet pipe flange.

EFFECT: facilitating transportation by self-centering along the longitudinal axis of the pump path of solid objects that are potentially dangerous to siltation, as well as objects from textile and similar materials by ensuring their mechanical twisting if their dimensions exceed the live section of the inlet pipe. In addition, an increase in pump suction force is provided.

The invention is illustrated by drawings, where figure 1 shows the design of the device in longitudinal section; figure 2 is the same, in cross section along aa; figure 3 is a design variant with a flange mounted on an elongated outlet pipe; figure 4 is an embodiment of the mounting of the inlet pipe in the housing; figure 5 - the implementation of the swirl.

The injection pump contains a tubular inlet 1 and an outlet 2 profiled nozzles that are installed along a common axis O-O in the housing 3 (see figure 1-3). The inlet pipe 1 has an inlet part 11, a cylindrical part 12 and a pointed tip 13 forming a nozzle 14.

Between the outer surface 12 of the pipe 1 and the inner surface of the housing 3, an annular pressure chamber 4 is formed in which the swirler 5 is installed. The pressure chamber 4 is in communication with a fitting 31 mounted on the housing 3 for supplying an ejection fluid. The outlet pipe 2 in the form of a Laval nozzle has a confuser 21 and diffuser 22 parts with a size d _kp in the critical section. The pipe from the side of the confuser part 21 is installed in the housing 3 on the thread 23 with the possibility of movement in the axial direction to adjust the magnitude of the working gap h between the nozzle 14 and the confuser 21 part. The inner diameter d _{1 of the} inlet pipe is approximately equal to the size of the critical section d ₁ = (1.0-1.3) d _kp .

Opening the confuser part 21 is in the range of angles α ₁ = 55-65 °, the opening angle α _{2 of} the diffuser part is determined by the inner diameter of the outlet pipe 2 and does not exceed 30 ° (15-20 °). The ratio of the length of the confuser L _K to the diffuser L _D part in the axial O-D direction is L _K / L _D = 0.9-1.1. The fixing of the pipe 2 can be performed by any known method, for example, by means of a flange 33 (shown conditionally) fixed with screws in the threaded holes 24 of the housing 3. The output line can also be attached with the same flange.

The ratio of the inner diameter d ₂ of the output nozzle 2 (at the tip of the diffuser portion 22) and the supply pipe ₁ d 1 of d ₂ / d ₁ = l, 0-l, 5. The gap h between the nozzle 13 and the confuser part 21 is h = 0.2-10 mm, is selected depending on the working pressure of the ejection fluid supplied through the nozzle 31 to the pressure chamber 4.

Figure 3 shows a design variant of the pump with a flange 25 mounted on an elongated outlet pipe 2 of the Laval nozzle. Flange 25 is designed to connect the output line and can be strengthened by welding directly at the tip of the nozzle 2. Opening the confuser part 21 in this embodiment is α ₁ = 55-65 °, the diffuser part α ₂ = 10-20 °. The ratio of the length of the confuser L _K to the diffuser L _D part in the axial O-D direction is L _K / L _D = 0.22-0.26. If the pump is used in conjunction with an automatic control circuit and vacuum is required to be detected at its inlet, a pressure sensor (not shown) can be used for this purpose, fixed in the hole 16 in the body of the pipe 1.

Figure 4 shows an embodiment of the mounting of the supply pipe 1 in the housing 3. The pipe 1 is installed in the housing 3 on the thread 17, is provided with a sleeve 18 with a fastening in the form of a welded ring having holes 19. The position of the pipe 1 in the housing 3 is fixed by a lock nut 191. For mounting the pressure sensor in the hole 16 has a sleeve 161 with a thread.

Figure 5 shows a view of the outer surface of the swirler 5. It is made in the form of a sleeve 51, on the outer surface of which spiral through channels 52 are formed. Arrow 53 conditionally shows the direction of flow of the ejection fluid formed by one of the channels 52 lying in the observation plane at an angle β to the longitudinal axis of the sleeve 51. The angle β can be from 45 to 75 °. Accordingly, the direction of twisting of the fluid, provided due to the tangential location of the nozzle 31, must, within an acute angle, coincide with the direction of the channels 52.

The injection pump in the mode of transporting a stream of heterogeneous media works as follows. When the ejection fluid is supplied to the nozzle 31 located tangentially, the flow is twisted in the annular chamber 4 and through the spiral through channels 52 in the additionally twisted state enters the annular gap of width h. This gap, as indicated, is formed between the wall of the confuser part 21 of the outlet pipe 2 and the pointed tip 13 of the inlet pipe 1 forming the nozzle 14. The optimal size of the annular gap is adjusted during the adjustment of the pump by moving the pipe 1 along the thread 17 and / or the outlet pipe 2 along the thread 23. At the exit of the annular nozzle 14 in the zone of the critical section of the nozzle (size d _{kp is} shown) and then in the diffuser, the transported heterogeneous medium is mixed with the ejection fluid. The vacuum created in this case due to the known properties inherent in the Laval nozzle ensures the suction and transportation of the ejected heterogeneous medium in the direction of the tip of the diffuser of the outlet pipe 2.

It was experimentally established that when an object is present in a liquid heterogeneous medium in a field of twisting forces, it is oriented along the axis of pump 4, and this contributes not only to its efficient transportation, but also to impart the functions of a mechanical and / or hydrodynamic cleaning agent when silting the whole system. So, in particular, when simulating the transportation of a process using objects of fibrous materials in a liquid medium, the size of which in the entangled state exceeds the cross section of the pipe 1, when compressed air is supplied to the pipe 31 at a pressure of 6 atm, these objects are “shot” from the output pipe "At a distance of 10 meters or more. The latter circumstance indicates the high efficiency of the injection pump in the transportation system.

Thus, as shown by the above and other experiments, the facilitation of transportation by means of self-centering along the longitudinal axis of the path of the device of potentially hazardous siltation of solid objects, mechanical twisting and twisting of objects from textile and similar materials, the dimensions of which exceed the live section of the inlet pipe, as well as an increase in strength, is ensured. suction.

Claims (4)

1. An injection pump for transporting a heterogeneous medium, comprising a tubular inlet and outlet nozzles arranged in a cylindrical body with the formation of an annular axial clearance in the axial direction and a pressure chamber in the radial direction, and a nozzle installed in the housing for supplying an ejection fluid, characterized in that a swirl is additionally introduced ejection fluid installed in the pressure chamber on the inlet tubular pipe, made in the form of a sleeve, on the outer surface of which is formed through s helical channels open at its ends, the outlet is configured in the form of a Laval nozzle having a convergent and a diffuser portion with rectilinear generatrices convergent portion is mounted in the housing on the thread axially movable in an annular gap, wherein the opening angle confusor part of α ₁ = 55-65 °, the ratio of the length of the confuser L _K to the diffuser L _D parts in the axial direction is L _K / L _D = 0.22-1.1, and the ratio of the inner diameters of the tip of the outlet d ₂ and the inlet d ₁ nozzles is d ₂ / d ₁ = 1.0-1.5. 2. The pump according to claim 1, characterized in that the through spiral channels are placed at an angle β = 45-75 ° to the longitudinal axis of the sleeve. 3. The pump according to claim 1, characterized in that the inner diameter d _{1 of the} inlet pipe is d ₁ = (1.0-1.3) d _kp , where d _kp is the diameter of the critical section of the Laval nozzle of the inlet pipe. 4. The pump according to claim 1, characterized in that a flange is installed at the tip of the outlet pipe.

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