RU26610U1 - Non-clogging pump - Google Patents

Description

Non-clogging pump

The utility model relates to sanitary engineering, and can be used for pumping wastewater, its sludge containing solid, abrasive inclusions and long-fiber substances.

Centrifugal blowers 1,2 are known, which have various systems for protecting the casing and blades from wear, but when pumping wastewater and their sediments containing solid, abrasive inclusions, these systems do not solve the problem of eliminating clogging, wear and vibration of mechanisms.

To reduce the frequency of clogging of the flow parts of the pumps with suspended and long-fiber substances, the dimensions of the inter-blade space are increased by reducing the number of blades. This leads to the use of single-blade impellers. The operating experience of such pumps (Flygt, Sarlin, etc.) at the facilities of Vodokanal St. Petersburg State Unitary Enterprise showed that due to the uneven wear of the surface of the blades, the occurrence of vibration occurs several times faster compared to multi-vane pumps.

The authors of this utility model propose a free-vortex pump scheme, on the basis of which pump designs for pumping wastewater and their sludge containing solid, abrasive inclusions and long-fiber substances can be created.

The closest analogue to the claimed utility model is "Wear-resistant blower according to the patent of the Russian Federation J4o2079724, class. F04 D7 / 04, 1997. The wear-resistant supercharger has a spiral casing, an impeller with blades installed in it, partially located in the bezel of the rear wall of the casing, an inlet pipe, the outlet cross section of which is located with a gap relative to the impeller blades. In this case, the niche is made in the form of a truncated cone, the relative diameter of the smaller base is co20021T9518

) 1 | .2 JO 02

the slope of the generatrix of the conical surface a 37.5, the relative width of the spiral housing b - 0.42 - 0.5 and the relative opening of the back. . A . . ..:

A ral body 0.2 - 0.25, and the inlet pipe is deepened in

case, and its relative diameter d 0.4-0.45, where dj is the diameter

the smaller base of the truncated cone; D2 - detectable wheel diameter; bi the width of the truncated cone; B2 is the width of the spiral casing; A - opening of the spiral case; do is the diameter of the inlet pipe.

The specified wear-resistant supercharger has the following disadvantages:

1. Clogging of the flowing part with large inclusions contained in the wastewater and its sediments, since only partial placement of the impeller in the recess of the rear wall of the casing, the design of the casing in the form of a spiral with a relative opening A 0.2 - 0.25, suggests a minimum flow section in the flowing part no more than 0 .. For pumping sewage sludge this is not always enough. For example, with mm, the minimum size of the flow passage cross section is 0. 0. mm. When pumping sewage sludge, such a pump will become clogged, as experience shows that the minimum passage size should be at least 80 mm.

2. Unstable operation of the pump (unstable flow), because:

-when pumping sewage sludge, a natural change in time of viscosity and the content of long-fiber substances is characteristic, therefore, as experience in operating experimental pumps shows, when pumping this medium and the relative width of the spiral casing

B-) b 0.35 there is a separation of the pumped medium from the vortex. In Protopia

ne this value is recommended to be changed in the range from 0.42 to 0.5, which does not take into account the peculiarities of pumping wastewater and its precipitation;

- when pumping sewage sludge saturated with gases - fermentation products, in the rarefaction zone in the pump housing due to a sharp decrease in pressure, dissolved gases are released and accumulated in its upper part. In this case, there is a significant decrease (in some cases to 0) of the pump performance.

3. Unreasonably oversized dimensions, because:

- the recommended relative width b 0.2-0.3 is significantly overestimated. The experience of experimental pumps shows that when

  0.1-0.bi 0.1-0.15 pumps operate stably. Application is recommended

relative width blown in the prototype will not only lead to a 2-fold increase in the width of the impeller, but also as a result of an increase in the cantileverness of the drive shaft, an increase in the radial load on the bearing assembly;

- the recommended impeller design using only full-sized blades allows you to achieve the required pressure only with an overestimated impeller diameter. The latter is explained by the fact that at the exit of such an impeller there are turbulences, since the gap between the blades is overextended. The use of the recommended design leads not only to an increase of up to 120% in the diameter of the impeller, but also as a consequence of an increase in the axial load on the bearing assembly.

The objective of the utility model is to ensure non-clogging, operation stability and reduction of the installation dimensions during the pumping of wastewater and their sludge containing solid, abrasive inclusions and long-fiber substances.

ENTRANCE nozzle with a clearance relative to the impeller blades, in accordance with our utility model, the impeller is completely located in the recess of the rear wall of the housing, which is made in the form of a body of rotation based on the union of a rectangle of width bi and height hi di / 2, a rectangle of height hi (di- 2hi) / 2 and a width b3 bi-r i, a semicircle of radius r 1 L / 4 around the axis coincides with the axis of rotation of the impeller. Wherein:

- clearance of the inlet pipe relative to the impeller blades

-relative inner diameter of the niche d 0.8-0.9; -relative outer diameter of the niche 6/2 1.05-1.1;

- the relative width of the housing 2 is 0.23-0.3 with 2 - the relative depth of the niche b is 0.07-0.1, where di is the internal

beggar diameter; d2-outer diameter of the beggar; D - detectable wheel diameter; bi is the depth of the niche; B2 is the width of the body; s is the maximum size of solids contained in the pumped medium.

In addition, the housing is additionally equipped with a discharge pipe connected to its upper point, the impeller is additionally equipped with a rear disc and peripheral shortened blades. Moreover, the length of the peripheral shortened blades / i 0.2 D and they are placed between the working blades at a distance of / 2 0.3 D from the center of the impeller, the angle of inclination of the inner edge of the peripheral shortened blades / 60.

Distinctive features of the claimed non-clogging pump are:

1. Full placement of the impeller in the beggar of the rear wall of the housing;

L

3. The implementation of the rear wall niche in the form of a body of revolution based on the union of a rectangle of width b | and height h | di / 2, a rectangle of height h2 (d2 - 2hi) / 2 and a width of bz brg j, a semicircle of radius r | A / 4 around an axis coinciding with the axis of rotation of the impeller. Here di is the inner diameter of the niche; d2-outer diameter of the niche; bi is the depth of the niche;

4. The implementation of a niche with a relative inner diameter of c / j 0.8-0.9, where D is the detectable diameter of the wheel;

5. The implementation of a niche with a relative outer diameter d2 1.05-1.1;

6. Niche execution with relative depth &0.07-0.1;

7. The execution of the housing with a relative width of b - 0.2-0.3

when 2 - where S is the maximum size of solid inclusions contained in the pumped medium;

8. Additional supply of the body with a branch pipe connected to its upper point;

9.Additional supply of the impeller with a rear disc;

10. Additional supply of the impeller with peripheral shortened blades with a length of 1 0.2 D;

11. The location of the peripheral shortened blades between the blades at a distance of / 2 0.3 D from the center of the impeller;

12. The angle of inclination of the inner edge of the peripheral shortened blades at 60 °.

According to the information available to the authors, the distinguishing features No. 8 and 9 in the technical literature are known, and the rest are not. However, their combined use in the claimed device allows to obtain three new effects.

The first new effect is that a new property of the pump appears - non-clogging of the flow part with large inclusions during the pumping of sewage and their precipitation, because there are no places in it whose size is less than the maximum particle size characteristic of the pumped medium;

The second new effect is that a new property of the pump appears - the stability of operation during the pumping of wastewater and their sediments saturated with dissolved gases and containing long-fiber substances. The latter is achieved by the fact that, firstly, the additional supply of the housing with a discharge pipe attached to its upper point will prevent the accumulation of released gases, since they will be constantly discharged through the discharge pipe. Secondly, the execution

case with a relative width of 2 0.23-0.3 at will allow (in

in accordance with the results of experimental studies) to exclude the separation of the pumped medium from the vortex;

The third new effect is that due to the new design of the impeller and the niche, the dimensions of the installation are reduced.

Thus, the claimed non-clogging pump meets the criterion of "inventive step.

The non-clogging pump proposed by the authors is structurally different from the prototype.

In FIG. 1 and FIG. 2 shows sections A-A of the pump, a general view of which is shown in FIG. At the same time, in Fig.1 shows a section of the pump assembly, and in Fig.2 only its body.

In FIG. 4 is a general view of the impeller; FIG. 5 is a section along BB. In addition, figure 6 shows the parametric characteristics of non-clogging pumps, successfully passed the test.

Non-clogging pump contains (see figL, 2, 3,4, 5):

-casing 1, the relative width of which 2 is 0.2-0.3 at

2 -5, where D is the detectable diameter of the wheel; B is the width of the body; s is the maximum size of solids contained in the pumped medium;

- a niche 2 in the rear wall of the housing 1, made in the form of a body of ingrowth; based on the union of a rectangle ABCD of width b, height, KEDI rectangle of height h2 (da- 2hi) / 2, width b3 and a semicircle of KAE with radius r D / 4 around the axis coinciding with the axis of rotation of the impeller 3. The relative internal diameter of the niche Jj 0.8-0.9,

relative outer diameter of the niche with / 2 1.05-1.1, relative

its depth i 0.07-0.1;

- impeller 3 with a rear disk 4, blades 5 and peripheral shortened blades 6 completely located in a recess 2 of the rear wall of the housing 1. Moreover, the length of the peripheral shortened blades 1 0.2 D and they are placed between the blades at a distance of / 2 0.3 D from the center the impeller 3, and the angle of inclination of the inner ribs of the peripheral shortened blades / 3 60 °;

-inlet pipe 7 with a gap relative to the blades 5 and 6 of the impeller 3;

- outlet pipe 8 connected to the upper point of the housing 1.

Non-clogging pump operates as follows.

When the impeller 3 rotates in a niche 2 of the housing 1, a powerful vortex of the transported liquid arises, which ensures the creation of the necessary pressure and performance of a non-clogging pump.

During operation of a non-clogging pump, only part of the liquid passes through the blades of the impeller, a significant part of it passes the blades, and under

the action of the vortex created by the wheel, moves from the entrance to the discharge pressure pipe 8.

The impeller 3 is completely located in the beige 2 of the rear wall of the housing 1 so that the edges of the 12 blades 5 and 12 peripheral shortened blades 6 are in the plane of the surface of the rear wall of the housing. A non-clogging pump does not have a seal at the inlet to its housing.

The relative dimensions of the non-clogging pump were determined experimentally. SUE Vodokanal of St. Petersburg and AViV LLC carried out tests on prototypes under conditions of pumping sewage sludge, after which the best option was found. The parametric characteristics of non-clogging pumps that successfully pass the tests are shown in FIG. 6. Here: 1 - H-Q characteristic at various speeds; 2 - N-Q characteristic.

1. The author's certificate of the USSR No. 1731997, cl. F04 D7 / 04, 1992;

2. UK patent No. 1255948, CL F04 D7 / 04, 1968;

3. RF patent No. 2079724, cl. F04 D7 / 04, 1997.

Claims (2)

1. Non-clogging pump, comprising a housing with a niche, an impeller with vanes installed in it, an inlet pipe with a gap relative to the impeller blades, characterized in that the impeller is fully placed in the rear housing wall niche, the inlet pipe gap relative to the impeller vanes Δ = b ₂ , the niche is made in the form of a body of revolution based on the union of a rectangle of width b ₁ , height h _i = d _1/2 , rectangle of height h ₂ = (d ₂ -2h _i ) / 2, width b ₃ = b ₁ -r ₁ and a semicircle of radius r ₁ = Δ / 4 around an axis coinciding with the axis of rotation of the working the wheel, while the relative inner diameter of the niche d ₁ = d ₁ / D = 0.8-0.9, the relative outer diameter of the niche d ₂ = d ₂ / D = 1.05-1.1, the relative width of the housing b ₂ = b ₂ / D = 0.2-0.3 with b ₂ ≥s, the relative depth of the niche is b ₁ = b ₁ / D = 0.07-0.1, the housing is additionally equipped with a discharge pipe connected to its upper point, the impeller is additionally equipped with a rear disc and peripheral shortened blades, where d ₁ is the inner diameter of the niche; d ₂ is the outer diameter of the niche; D is the outer diameter of the wheel; b ₁ - the depth of the niche; b ₂ is the width of the housing; s is the maximum size of solids contained in the pumped medium. 2. Non-clogging pump according to claim 1, characterized in that the length of the peripheral shortened blades 1 ₁ = 0.2 D and they are placed between the working blades at a distance of 1 ₂ = 0.3 D from the center of the impeller, the angle of inclination of the inner ribs of the peripheral shortened blades β = 60 ^o .