RU2641781C1 - Pneumatic dewatering pump - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: pump has a hollow body, a pressure branch pipe with a valve, a suction branch pipe with a valve, a corrugated hose and a filter, a cover with fixed pneumatic switch having a body with a chamber. The pump has a cylindrical float, a holder, a rod, a valve, a cover with a seat and a drain hole, a guide basket with a bottom for placing and moving the float. It also has an inlet branch pipe for compressed air supply, an ejector with nozzle, and a chamber. The ejector with pump body is communicated by a nipple joint and a pneumatic switch by a connecting tube. The inlet branch pipe for supplying compressed air to the ejector is provided with an adjusting device connected to the ejector by an adapter. The connecting tube that connects the ejector to the pneumatic switch is installed tangentially to the chamber of pneumatic switch body and configured with the Laval nozzle in the middle part. A flow stabiliser is installed in the pneumatic switch chamber and configured in the form of a vertical plate fixed in front of the connecting tube inlet into the chamber of the pneumatic switch body in the air flow direction inside the chamber.

EFFECT: duration of the total cycle for filling and emptying the body with water is reduced, pump capacity is increased.

3 cl, 3 dwg

Description

The invention relates to the field of pump engineering and relates to pneumatic displacement pumps designed for pumping contaminated water, in particular in mines and mines of any category of complexity in gas and dust, and can be used in modernized pneumatic drainage pumps of the type “NVP-1 U5”.

The prior art pneumatic sump pump [1], comprising a hollow body with a working chamber, an inlet suction pipe with a valve for water intake, an outlet pressure pipe with a valve for water drainage, a float connected by a rod to a valve located in the cavity of a pneumatic switch equipped with a drainage a hole, an air duct for supplying compressed air, an ejector with a nozzle in which the axial inlet communicates with the air duct, the transverse inlet communicates with the working chamber of the housing, and the axial outlet communicates with the pneumatic cavity eklyuchatelya [ "air pump replacement» SU 1456648 (A1) (All-Union Scientific Research Institute of organization and mechanization of mine construction) F04F 1/06, 07.02.1989].

The float is made of hollow lever type, pivotally mounted on a lever to which a rod is attached kinematically connected to the pneumatic switch valve. The inlet suction pipe with a valve for water intake is installed in the upper part of the end of the housing and is located horizontally. The outlet discharge pipe with a valve for draining water is installed vertically in the housing at a certain distance from the lower inner surface of the housing.

The disadvantages of the known pump [1] are low reliability and lack of efficiency. Low reliability of the pump due to the fact that the design of the pump used float lever type. As a result, with large displacements of the float at the end of the lever, the valve stem makes much smaller displacements, that is, it has a small stroke. Because of this, with such small movements of the stem, it is impossible to ensure accurate and efficient adjustment of the pneumatic switch and reliable operation of the pump.

In addition, the lack of efficiency of the pump is also due to the need for periodic removal of sediment from the cavity of the housing. The accumulation of bottom sediment is caused by the fact that the bottom of the body is horizontal, and the outlet discharge pipe with a valve for draining water is installed vertically at a certain distance from the bottom of the body in the body, and cannot remove sediment from the entire bottom surface of the body cavity.

In this case, the accumulation of sediment significantly reduces the efficiency of the pump and necessitates its periodic and laborious cleaning.

The prior art also known for the prototype, the closest to the claimed technical solution for the purpose, technical essence, the number of common features and the technical result achieved, pneumatic drainage pump [2], containing a hollow body, a discharge pipe with a valve, a suction pipe with a valve , with a corrugated sleeve and filter, a cover on which a pneumatic switch is mounted, including a cylindrical float, a clip, a rod, a valve, a cover with a saddle and a drainage hole, and a body with a camera, a cleaning basket with a bottom for placement and movement of the float, as well as an inlet pipe for supplying compressed air, an ejector with a nozzle and a chamber, the ejector with a housing communicated by means of a nipple connection, and with a pneumatic switch - a connecting tube [“Water-driven pneumatic pump НВП-1 У5 UA77464 (U) (Gabuniya Yu.N.) F04F 1/00; F04F 1/06, 02/11/2013].

In the known pump [2], a pneumatic switch comprising a cylindrical float, a clip, a rod, a valve, a cover with a seat and a drainage hole and a housing with a camera, a guide basket with a bottom for placing and moving the float, located on one vertical axis, which significantly increases its efficiency work in comparison with the lever design of the pump [1].

The disadvantage of this pump [2] is its lack of performance of 9-6 m ³ / hour. This is caused by the fact that the process of filling the housing with pumped water takes place at an insufficiently high pace, which increases the duration of the general cycle of filling and emptying the housing with water.

The technical problem to be solved by the claimed invention is directed is to eliminate the disadvantage of the prototype.

The technical result that is achieved by solving the technical problem and using an improved pump is to reduce the duration of the total cycle of filling and emptying the housing with water by increasing the speed of compressed air after the ejector through the connecting pipe, as well as through the chamber and drain hole of the pneumatic switch cover and the possibility pressure regulation of the speed of compressed air at the inlet to the ejector, which significantly increases the performance of the pump itself.

The technical task is solved, and the technical result is achieved by the fact that a pneumatic drainage pump containing a hollow body, a discharge pipe with a valve, a suction pipe with a valve, a corrugated sleeve and a filter, a cover on which a pneumatic switch including a cylindrical float, a clip, a rod is fixed , a valve, a cover with a seat and a drainage hole, and a body with a camera, a guide basket with a bottom for placement and movement of the float, which are located on the same vertical axis, as well as the entrance second conduit, for supplying compressed air to the ejector nozzle and the chamber, the ejector communicates with the housing by means of pin connection, and with pnevmopereklyuchatelem - connecting tube, according to the claimed invention includes the following novel features:

- the inlet pipe for supplying compressed air to the ejector is equipped with an adjustment device connected to the ejector adapter;

- a connecting tube connecting the ejector to the pneumatic switch is mounted tangentially to the chamber of the pneumatic switch housing and is made in the middle part with a tapered tapering channel - a confuser associated with an expanding conical channel - a diffuser, by means of an intermediate bypass cylindrical channel - a critical section, which together form a Laval nozzle ;

- a flow stabilizer is installed in the chamber of the pneumatic switch housing, made in the form of a vertical plate fixed in front of the entrance of the aforementioned connecting tube into the chamber of the pneumatic switch housing along the air flow inside the chamber;

- the pneumatic switch further includes a sleeve mounted inside the cage, and said sleeve and the pneumatic switch rod passed through it are made of high-strength bronze.

The use of an adjusting device, for example, in the form of a valve with a valve or in the form of a reducer that reduces compressed air, allows you to adjust the pressure and speed of the supplied compressed air to the inlet of the ejector. This provides the choice of compressed air parameters necessary to create the most optimal mode of operation of the ejector, in which there is an effective suction of air from the housing when filling it with water, or forcing air into the housing when it is emptied, as well as to supply a high-speed jet of air into the connecting tube, connecting ejector with pneumatic switch.

The implementation of the connecting tube connecting the ejector with the pneumatic switch, in the form of a Laval nozzle, provides an increase in the flow rate of compressed air at the outlet from it and at the tangential entrance to the chamber of the pneumatic switch housing.

At the same time, the flow stabilizer, made in the form of a vertical plate fixed in front of the entrance of the connecting tube into the chamber of the pneumatic switch housing in the direction of the air flow inside the chamber, provides directional movement of the said air flow to the drainage hole of the cover of the pneumatic switch housing without significant loss of its expiration rate.

The introduction of an additional sleeve installed inside the cage into the pneumatic switch and made like a pneumatic switch rod made of high-strength bronze passed through it allows to significantly reduce sliding friction between the movable rod and the pneumatic switch sleeve, which increases reliability and reduces the delay time of the pump pneumatic switch. For example, three full cycles of pump operation occur in 53 seconds, while the prototype has two full cycles of operation in 1 minute 25 seconds.

Due to such design features of the pump, it is possible to reduce the duration of the general cycle of filling and emptying its body with water, which significantly increases the productivity of the pump itself by almost 1.5-2 times to 12-9 m ³ / h, and the vacuum gauge suction height increases from 4 to 8 m

The proposed pump has other differences that create an additional technical result. For example, the ability to operate the pump on an inclined support plane with a roll of the housing from 0 to 25 °. So, due to the fact that the hollow float of the switch is fixed to the rod with a bolt freely, and the execution of a high-strength bronze rod and switch sleeve allows you to reduce sliding friction, even on an inclined plane, free up / down sliding of the entire pneumatic switch chain is ensured.

In addition, in the proposed pump, according to the invention, the cover of the pneumatic switch is made of stainless steel. This significantly increases the life of the pump in a flooded area.

In the future, the proposed pneumatic sump pump is illustrated by an example of its implementation with reference to the accompanying drawings.

In FIG. 1 shows a pneumatic sump pump, general view.

In FIG. 2 shows a pneumatic sump pump, fragment.

In FIG. 3 shows a section AA in FIG. 2.

The pneumatic drainage pump (Fig. 1-3) contains a hollow body 1, a pressure pipe 2 with a valve 3, a suction pipe 4 with a valve 5, a corrugated sleeve 6 and a filter 7, a cover 8, on which a pneumatic switch 9 is fixed.

The pneumatic switch 9 includes a cylindrical float 10, a holder 11, a stem 12, a valve 13, a cover 14 with a seat 15 and a drainage hole 16, and a housing 17 with a chamber 18, a guide basket 19 with a bottom 20 for accommodating and moving the float 10.

The pump also includes an inlet pipe 21 for supplying compressed air, an ejector 22 with a nozzle 23 and a chamber 24, and the ejector 22 with the housing 1 is communicated through a nipple connection 25, and with a pneumatic switch 9 - a connecting pipe 26.

The main features of the proposed pump are the following improvements in its design.

The inlet pipe 21 for supplying compressed air to the ejector 22 is equipped with an adjustment device, shown in the form of an adjustment valve 27 connected to the ejector 22 with an adapter 28.

The connecting tube 26 connecting the ejector 22 to the pneumatic switch 9 is installed tangentially to the chamber 18 of the housing 17 of the pneumatic switch 9 and is made in the middle part with a tapered tapering channel - confuser 29, coupled to an expanding tapered channel - diffuser 30, through an intermediate bypass cylindrical channel - critical section 31, which together form a Laval nozzle 32.

An air flow stabilizer 33 is installed in the chamber 18 of the housing 17 of the pneumatic switch 9, made in the form of a vertical plate fixed in front of the entrance of the connecting tube 26 into the chamber 18 of the housing 17 of the pneumatic switch 9 in the direction of the air flow inside the chamber 18. The pneumatic switch 9 further includes a sleeve 34 installed inside cages 11, and the said sleeve 34 and the rod 12 of the pneumatic switch 9 passed through the cage 11 are made of high-strength bronze, for example, grade BRAZH 9-4.

The hollow body 1 is made in the form of a horizontally arranged cylindrical shell with rounded end walls and is mounted on the support slide 35 with an inclination towards the outlet discharge pipe 2 at an angle α = 1-50.

Due to such improvements in the design of the pump, it is possible to reduce the duration of the general cycle of filling and emptying the housing with water, as well as the ability to work on an inclined supporting plane with a roll of the housing from 0 ° to 25 °.

In addition, the cover 14 of the pneumatic switch 9 is made of stainless steel, for example grade 07X16H6, which significantly increases the service life of the pump in a flooded space.

In unforeseen situations, such as sudden flooding of mine workings in mines, mines and quarries, this pump can be used as a submersible pump. In this case, the immersion depth of the pump, for example, in the barrel can be up to 110 m.

The pump operates as follows.

For example, a pump used in a mine with its support slides is installed horizontally or with a slight roll in the flood zone on a support surface, while the filter 7 of the suction pipe 4 is buried in the pumped water using a flexible corrugated sleeve 6, and a technological flexible pipe is connected to the outlet discharge pipe 2 sleeve for draining water into the catchment.

In the initial position in the pump, the cylindrical float 10 and the stem 12 under the influence of their own weight are in the lower position, that is, on the bottom 20 of the basket 19, the valve 13 is located in the lower part of the chamber 18 of the cage 11 of the pneumatic switch 9 in the “open” position, the drain hole 16 in the cover 14 of the pneumatic switch 9 is also open.

The control valve 27 for supplying compressed air, the valve 5 of the suction pipe 4 and the valve 3 of the pressure pipe 2 are in the "closed" position.

Before starting work, the control valve 27 moves the valve (not shown in the figures) from the "closed" position to the "open" position.

When compressed air is supplied to the inlet 21, compressed air, for example, under a pressure of 0.18-0.60 MPa, enters the control device shown in the figure as control valve 27, which controls the necessary flow rate and pressure of the air flow through adapter 28 to ejector 22.

In the nozzle 23 of the ejector 22, the air flow is accelerated, and at the exit of the nozzle 23 enters the connecting tube 26.

In the connecting tube 26, made in the middle part with a tapered tapering channel - confuser 29, paired with an expanding tapered channel - diffuser 30, through an intermediate bypass cylindrical channel of critical section 31, which together form a Laval nozzle 32, the air flow is further accelerated.

Next, the tangential air flow enters the chamber 18 of the housing 17 of the pneumatic switch 9, where it makes a turn inside the chamber 18 and enters the stabilizer 33, which through the open drainage hole 16 in the cover 14 of the pneumatic switch 9 directs the accelerated air flow out into the atmosphere.

At the same time, a vacuum is created in the transverse inlet of the chamber 24 of the ejector 22 through the nipple joint 25.

As a result, air from the working chamber of the housing 1 is sucked out through the nipple connection 25, enters the chamber 24 of the ejector 22 and, together with the main high-speed flow through the connecting tube 26, which is a Laval nozzle 32, tangentially enters the chamber 18 of the housing 17 of the pneumatic switch 9 .

In the pneumatic switch 9, the generalized high-speed air flow makes a revolution inside the chamber 18 and enters the stabilizer 33, which directs the accelerated air flow out into the atmosphere through the open drainage hole 16 in the cover 14 of the pneumatic switch 9.

As a result, the pressure in the working chamber of the housing 1 becomes less than atmospheric, the valve 3 of the pipe 2 closes and water through the filter 7, the flexible corrugated sleeve 6 opens the valve 5 and enters the working chamber of the housing 1 through the suction pipe 4, filling it with water, i.e. the operating mode of the pump is “suction”.

When this hollow cylindrical float 10 floats in the water and rises inside the guide basket 19 up together with the rod 12 and the valve 13.

When the working chamber of the housing 1 is completely filled with water, the hollow cylindrical float 10, stem 12 and valve 13 are in the upper position.

In this upper position, the valve 13 sits on the seat 15, closes the drainage hole 16 of the cover 14 of the pneumatic switch 9 and is in the "closed" position.

The output of the high-speed air flow through the axial output of the nozzle 23 of the ejector 22 is stopped, as a result of which compressed air under atmospheric pressure enters through the transverse outlet from the chamber 24 of the ejector 22 and the nipple connection 25 into the working cavity of the housing 1, completely filled with water.

The pressure in the working chamber of the housing 1 increases, the valve 5 of the suction pipe 4 closes, and the valve 3 of the pressure pipe 2 opens.

In this case, water from the working chamber of the housing 1 under the action of the pressure of compressed air entering the inlet pipe 21 through the nipple connection 25 is displaced through the discharge pipe 2 and is subsequently removed, for example, into the water collector (not shown in the drawing), i.e. the operation mode of the pump “discharge" is set.

Due to the fact that the housing 1 is mounted on the support slide 35 with an inclination towards the outlet discharge pipe 2 at an angle α = 1-50, an effective and intensive water outlet is provided together with particles suspended in it, including sediment particles, concave bottom of the inclined cylindrical shell of the housing 1, as in an inclined groove.

As the emptying and lowering the water level in the working chamber of the pump housing 1, the hollow cylindrical float 10 does not fall, but is still supported in the guide basket in the upper position by the air pressure in the cavity of the housing 1, which corresponds to the pressure of the compressed air entering the inlet pipe 21 (0.18-0.60 MPa).

The valve 13 is still pressed against the seat 15, closes the drainage hole 16 of the cover 14 of the pneumatic switch 9 and is in the closed position.

Therefore, water from the cavity of the pump housing 1 is displaced until it is completely emptied under pressure equal to 0.18-0.60 MPa through the discharge pipe 2 and is thrown out through the connected sleeve with a capacity of 12-9 m ³ / h at a distance of 60-180 m

After complete emptying, the pressure in the cavity of the pump housing 1 drops sharply and the hollow float 10 drops sharply under the action of its own weight on the bottom 20 of the guide basket 19 together with the stem 12 and valve 13. In this case, the valve 13 moves away from the seat 15, opens the drainage hole 16 of the cover 14 of the pneumatic switch 9 and the output of compressed air through the axial output of the nozzle 23 of the ejector 22, the connecting pipe 26 with the Laval nozzle 32 and the drain hole 13 of the cover 14 of the pneumatic switch 9 is resumed.

Then begins the second cycle of the pump, similar to the first.

With further operation of the pump, the process of automatically switching the “suction” and “forcing” modes is repeated.

Thus, the proposed improvements to the pump due to the implementation of the connecting tube 26 with a Laval nozzle 32 connected to the chamber 18 of the pneumatic switch 9 tangentially, the presence of the flow stabilizer 33 in the said chamber 18, the introduction of the adjustment device 27 into the inlet pipe 21, as well as the introduction of the pneumatic switch 9 of the additional sleeve 34, mounted inside the holder 11, and made as well as the pneumatic switch rod 12 made of high-strength bronze passed through the sleeve, together allow achieving The claimed technical result is a reduction in the duration of the general cycle of filling and emptying the casing with water, which significantly increases the pump capacity by almost 1.5-2 times to 12-9 m ³ / h, the vacuum gauge suction height increases from 4 to 8 m, and the discharge water (pressure) reaches 60-180 m. In addition, the pump can operate on an inclined supporting surface with a roll of the housing from 0 ° to 25 °.

The pump can also be used as a submersible pump, while the immersion depth of the pump, for example in a mine shaft, can be up to 110 m.

The above data indicate the possibility of industrial applicability of a pneumatic sump pump, which can be widely used for pumping contaminated liquids, in particular in mines and mines of any category of gas and dust complexity.

Notation list

1) case

2) discharge pipe

3) pressure port valve

4) suction pipe

5) suction pipe valve

6) corrugated sleeve of the suction pipe

7) suction pipe filter

8) housing cover

9) pneumatic switch

10) pneumatic switch cylindrical float

11) pneumatic switch holder

12) pneumatic switch rod

13) pneumatic switch valve

14) air switch cover

15) saddle cover pneumatic switch

16) drain hole of the pneumatic switch cover

17) pneumatic switch housing

18) pneumatic switch chamber

19) pneumatic switch float basket

20) bottom of the pneumatic switch float basket

21) inlet pipe for supplying compressed air to the ejector

22) ejector

23) ejector nozzle

24) ejector chamber

25) nipple connection of the ejector to the body

26) ejector connecting pipe with pneumatic switch

27) control valve

28) adapter

29) conical tapering channel - confuser of the connecting pipe of the ejector with a pneumatic switch

30) expanding conical channel - diffuser of the connecting pipe of the ejector with a pneumatic switch

31) bypass cylindrical channel - a critical section of the connecting pipe of the ejector with a pneumatic switch

32) Laval nozzle connecting pipe ejector with pneumatic switch

33) pneumatic switch flow stabilizer

34) pneumatic switch housing sleeve

35) support slide.

Claims (3)

1. A pneumatic drainage pump containing a hollow body, a discharge pipe with a valve, a suction pipe with a valve, a corrugated sleeve and a filter, a cover on which a pneumatic switch is mounted, in the housing of which there is a chamber connected through an ejector to an inlet pipe for supplying compressed air by means of a connecting tubes, a pneumatic switch also includes a holder, a stem, a valve, a cover with a seat and a drainage hole, and a cylindrical hollow float and a guide located on the same vertical axis a basket with a bottom for moving it, and the ejector with a hollow pump casing is connected via a nipple connection, characterized in that the inlet pipe for supplying compressed air to the ejector is equipped with an adjustment device connected to the ejector with an adapter, and a connecting tube connecting the ejector to the pneumatic switch is installed tangentially to the chamber of the pneumatic switch housing and is made in the middle part with a tapered tapering channel - a confuser paired with an expanding tapered channel m - diffuser, via an intermediate cylindrical bypass channel - the critical cross section, which together form the Laval nozzle, and in front of said connection tube housing chamber in pnevmopereklyuchatelya set configured as a vertical plate attached along the air flow within said chamber, the flow stabilizer.  2. The pneumatic drainage pump according to claim 1, characterized in that the pneumatic switch further includes a sleeve mounted inside the holder, said sleeve and the pneumatic switch rod passed through it, made of high-strength bronze. 3. Pneumatic drainage pump according to any one of paragraphs. 1 or 2, characterized in that the cover of the pneumatic switch is made of stainless steel.

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