FI20170035A1 - sewage Pump - Google Patents

Abstract

The invention relates to a wastewater pump with a so-called closed impeller (1) having 2-4 blades and the front shield (2) of the impeller (1) forms a fixed part of the impeller (1) and the front edges (4) of the impeller (1) blade are in Figure 1, they are arched in such a way that they form an arc in the direction of rotation as one moves in a suction opening (8) towards the outer periphery, whereby a cloth (5) which has fallen into the impeller (1) slides due to the shape of the the leading edge (4) of the blade (3) and centrifugal force to the outer periphery (6) of the leading edge (4) and adhering between the leading edge (4) of the blade (3) and the opening (8) in the bottom portion (7) of the pump, preventing the cloth (5) from to spin. The arc angle (1) can vary between 60 and 120 degrees. The bottom portion (7) of the pump may be provided with one or more grooves (9) in which / which the cloth (5) gets stuck as the impeller rotates, the cloth (5) being either cut in two parts following the flow to the blade passages (10) or braked on such that it releases the leading edge (4) of the blade (3) and follows the flow to the blade passage (10). The number of grooves (9) may be one or more and they are outside the suction opening (8). The blades (3) may have a lowering C which can be 1-15 mm due to the bottom portion of the pump (7). According to an alternative solution, the bottom portion (7) of the pump may be provided with one or more projections (15) which prevent the cloth (5) from spinning, the cloth following the flow to the blade passage (10).

Description

The present invention relates to a sewage pump.

In double and multi-vane sewage pumps, the problem is clogging. Smaller sewage pumps use single-impeller impellers that do not have clogging problems, but have lower efficiencies than double- and multi-vane sewer pumps and, in addition, have higher vibration values and are therefore not used in larger pumps. In double- and multi-winged blockages, there has been such that the ends of the rags go into different wing blades and remain in the impeller entry space, supporting it.

To avoid clogging problems, a method is known in which the leading edges of the wings are made curved so that the distances between the leading edges of the wings are increased. Experience has shown that this tool has not been 100% helpful. In addition, this method degrades efficiency.

Another known method is to use the so-called. a semi-open impeller in which the impeller front plate does not rotate and there is a gap between the impeller blades and the front plate of the order of about 0.5 mm. The leading edges of the vanes are shaped to be curved when viewed from the front of the impeller so that an impurity (usually a rag) slides as the impeller rotates on the outer periphery of the leading edge and the aforementioned gap, cutting it and the cut ends flowing into different slots. The disadvantage of this solution is that the wear of the gap is reduced, whereby the efficiency is reduced and jamming caused by impurities can occur in the worn gap, overloading the motor.

The object of the invention is to eliminate the problems of clogging of the impellers of double- and multi-vane sewage pumps without a reduction in efficiency and without a reduction in efficiency as a result of wear and without the risk of jamming caused by wear.

2.

According to the invention, the object of the invention can be achieved by using the so-called a closed impeller in which the front plate is fixed and rotates with the impeller and the leading edges of the impeller blades are shaped to provide good efficiency. To prevent clogging of the impeller when viewed from the front, the leading edges of the vanes are curved so that the grooves slide to the outer circumference of the suction opening due to the shape and centrifugal force of the leading edges of the curved vanes. or cuts into two parts that go into different slots with the flow.

More specifically, the sewage pump according to the invention is characterized by what is set forth in the characterizing part of claim 1.

The invention will now be described in more detail with reference to the accompanying drawings 1 and 2.

Figure 1 shows a front view of a pump part and an impeller according to the invention. Figure 2 shows the bottom part and the impeller of the pump according to the invention in section A-A and in an alternative solution in section B-B.

The invention will now be described in more detail with reference to the accompanying drawings.

The impeller 1 can have a 2-4-bladed so-called a closed structure in which the front plate 2 of the impeller 1 is an integral part of the impeller 1 and rotates with it. A 2-bladed impeller is drawn in the picture, but it can also be 3- or 4-bladed.

The leading edges 4 of the wings 3 are curved in Fig. 1 so that they curve in the opposite direction to the direction of rotation when going to the outer circumference. In this case, the impeller 1 become cloth 5 slides on four shape and the centrifugal force of the vane 3 the leading edge of the leading edge 4 of the outer periphery 6 clinging to the vane 3 the leading edge of the pump of the base portion 4 and 7 of the opening 8 in between, preventing rag 5 rotating, when it comes off the front edge 4. Kaareutumiskulma α may be in the range of 60 ⁰ - 120 °.

The bottom part 7 of the pump may have a groove or grooves 9 or alternatively a protrusion or protrusions 15 into which the rag 5 engages as the impeller 1 rotates. In this case, the rag 5 either cuts into two parts, which go with the flow into the wing slot 10, or brakes so that it detaches from the leading edge 6 of the wing 3 and goes with the flow into the wing slot 10.

The grooves 9 may be one or more and the width B of the groove 9 may be, for example, between 10 and 50 mm according to experience. The depth A of the groove 9 can typically be between 5 and 15 mm. The radial length of the common gap 12 of the front plate 2 of the impeller 1 and the pump base part 7 should be between 5-10 mm at the ends in order to avoid leakage losses of the sealing gap. The recess C of the leading edge 4 of the vane 3 due to the bottom part 7 of the pump can be between 0-15 mm according to experience. The gap 13 between the pump base part 7 and the vane 3 can be between 2-5 mm according to experience. In an alternative solution, there may be one or more protrusions 15 and the width D of the protrusion 15 may typically be 5-10 mm and the height E typically 7-15 mm and the gap 16 between the protrusion 15 and the outer edge 6 of the leading edge 4 of the wing 3 is typically 0.5-5 mm.

In addition to non-clogging, the invention uses the so-called a closed impeller, in which case, with respect to the semi-open impeller, wear of the gap between the impeller blades and the fixed front plate is avoided, and thus the efficiency is reduced and the gap is jammed due to impurities. In addition, the closed impeller avoids increasing the distances to the leading edges of the wings, which would degrade efficiency. In the solution according to the invention, the center line 14 of the wings is made long, which improves the efficiency.

Within the scope of the invention, it is also possible to think of solutions that differ from those described, for example with regard to the dimensions shown therein, with respect to the curvature of the leading edge shown in the figure, for example so that it is smaller with respect to the outer edge 6 or grooves 9.

Here is described the solution of the so-called. with an end sealing gap, but the invention can also be implemented with a so-called sylinteriraolla. The figures show a submersible pump, but the invention can also be implemented in a dry-mounted pump with a suction pipe.

Claims (8)

Claims: 1. A double or multi-vane sewage pump with a so-called closed impeller characterized in that the leading edges (4) of the blades (3) of the impeller (1) are curved so that they curve in the opposite direction to the direction of rotation when going to the outer circumference. Sewage pump according to Claim 1, characterized in that the leading edges (4) of the vanes (3) are curved α = 60 ° -120 °. Sewage pump according to Claim 1, characterized in that the bottom part (7) of the pump has a groove or grooves (9) and the plate B of the groove (9) is between 10 and 50 mm and the depth λ = 5 to 15 mm. Sewage pump according to Claims 1 and 3, characterized in that the radial length of the common gap (12) of the front plate (2) and the pump base part (7) is 5 to 10 mm. Sewage pump according to Claim 1, characterized in that the immersion C of the vane (3) due to the bottom part (7) of the pump is between 0 and 15 mm. Sewage pump according to Claims 1 and 5, characterized in that the gap (13) between the pump base part (7) and the vane (3) is 2 to 5 mm. Sewage pump according to Claim 1, characterized in that the bottom part (7) of the pump has a projection or projections (15) and the width D of the projection (15) is between 5 and 10 mm and the height E = 7-15 mm. Sewage pump according to Claims 1 and 7, characterized in that the gap (16) between the projection (15) and the outermost part (6) of the leading edge (4) of the wing (3) is 0.5 to 5 mm.