CS254811B1 - Dredge pump - Google Patents

Abstract

The non-radial type centrifugal pump is intended for hydraulic conveying of a mixture of liquid and solid particles. The purpose is to prevent the pump from seizing by stones jammed between the impeller blades and the pump body and to increase the pump service life. The purpose is achieved by the impeller being provided with a ring which, with its pressure and vacuum edges, exceeds the outlet and leading edges of the blades. An inlet and outlet ring are connected to the inlet and outlet edges. The inlet collar and the impeller ring have an axial overlap and there is a radial gap between them, which is also between the outlet collar and the ring. In the space defined by the outer surface of the ring, the inner wall of the pump body and the planes </· , fi, at least one overpressure elastic circular sleeve and at least one underpressure elastic circular sleeve are placed. The planes «4 · Λ are perpendicular to the longitudinal axis of the pump. An inlet channel is located between the vacuum and overpressure elastic circular cuff.

Description

The invention relates to a dredging pump of a non-radial type suitable for use in the hydraulic transport of a mixture of liquid and solid particles.

A drawback of the known dredging pumps of the non-radial type is that stones between the impeller blades and the pump housing are penetrated, which very often causes the pump to seize. Further, the space between the pump housing and the impeller is constantly washed by a certain amount of solid-particulate hydrosulfuric compound which acts abrasively on the impeller parts and the adjacent pump body parts, resulting in a relatively low device life.

Said drawbacks are eliminated by the dredging pump according to the invention, characterized in that the outer periphery of the impeller blades is provided with a ring whose pressure edge extends beyond the trailing edge of the overlapping blades and the vacuum edge overlaps the leading edge of the overlapping blades. An input flange is attached to the input edge of the rear body, and an output flange is attached to the output edge of the front body. The inlet collar and impeller ring have an axial overlap on the pressure edge side of the impeller ring and a radial gap between them. The outlet collar and impeller ring have an axial overlap on the vacuum edge side and a radial gap between them. In the space defined by the outer surface of the impeller ring, the inner wall of the pump housing and the planes α and / 3, there is at least one overpressure flexible ring collar on the pressure edge side of the ring and at least one underpressure flexible ring collar on the vacuum edge side of the ring. The planes cL and β are perpendicular to the longitudinal axis of the pump, the planes pass through the pressure edge of the ring and the plane plane passes through the outlet edge of the front body. Mezi pod2

At least one inlet duct is provided with a thick elastic ring collar and a pressurized flexible ring collar. The ring consists of a body, a vacuum adapter and a pressure adapter. The vacuum adapter and the pressure adapter are connected to the ring body from each side so that they overlap them externally over its entire circumference and are axially displaceable thereafter. The ring body is provided with replaceable inserts in portions adjacent the pressure surface of the vanes on the pressure edge side of the ring. The pressurized resilient ring collars and the depressurized resilient ring collars are attached to the inner wall of the pump body or to the outer surface of the impeller ring and with their opposite edge extend to the outer surface of the impeller ring or the inner wall of the pump body.

An advantage of the device according to the invention is that the risk of seizing of the pump by stones stuck between the impeller blades and the pump housing is eliminated and the transmission of the hydros mixture between the pump housing and the impeller ring is greatly reduced, thereby increasing the dredging pump life.

An example according to the invention is shown in the schematic drawings Fig. 1 is a longitudinal section through the dredging pump; Fig. 2 is a view of the impeller from the bearing side; and Fig. 3 is a partial cross-section of the impeller ring.

The dredging pump consists of a pump housing 1 in which the impeller 2 is mounted in the bearing 9. The pump housing 1 consists of a front body 10 located in front of the impeller 6 and a rear body 11 located behind the impeller 2.

The front body 10 and the rear body 11 are connected by a connecting part 12 which forms the distributor chamber 8. The impeller 2 consists of a hub 3, blades 4 and a ring 2 which is connected to the outer circumference of the blades 4. This arrangement prevents the stones from jamming between the blades 4 of the impeller 2 and the pump body 1. The impeller ring 5 consists of a body 27 , an underpressure extension 6 and an overpressure extension 7 which surround the body 27. An inlet flange 13 is connected to the inlet edge 15 of the rear body 11 and an outlet flange 14 is connected to the outlet edge 16.

254 811 and the outlet collar 14 cause the interior of the distributor chamber 8 to be mechanically protected against the penetration of abrasive solid particles in the radial plunger from the interior of the pump. Both the overpressure adapter and the underpressure adapter 6 are axially displaceable on the body 27 of the ring 5. This makes it possible to define the necessary overhangs h and m as they are reduced by wear to the limit value. The overlaps k of the impeller ring 2 with respect to the trailing edge 22 and the leading edge 24 of the blades 4 serve to optimize the relative circumferential velocity component of the pumped hydro-mixture around the gaps 17, further contributing positively to the service life of the ring 5 and pump housing. located in the ring 5 of the impeller 2 close to the pressure surface 23 of the vane 4 on the side txakdv3hi. the edges 28 of the ring 5 extend the life of the impeller 2, since this location is extremely exposed to the abrasive solid particles of the water mixture. Pure flushing water is fed to the manifold chamber 8 via one or more inlet ducts 20, 18 under vacuum.

weighing elastic ring sleeve and the pressurized elastic annular cuff 19, which are located between the inner wall 26 of pump body 1 and the outer surface 2y of the ring ^ _r have a function that provides uniform distribution of the flushing clean water from the distribution chamber into the radial gap 17, which further limits the penetration of abrasive particles by radial gaps 17 from the interior of the pump into the distribution chamber 8.

Claims (6)

SUBJECT OF THE INVENTION 254 Bil A dredging pump comprising a pump housing, comprising a front and a rear housing, between which a connecting part forming a distribution chamber with inlet ducts, a bearing and an impeller, located between the rear housing and the front housing, have fallen, characterized in that the outer circumference the impeller blades (4) are provided with a ring (5) which, with its pressure edge (28), extends beyond the trailing edge (22) of the blades (4) with an overlap (X) and the vacuum edge (29) extends beyond the leading edge (24) blades (4) with overlap (k), the inlet edge (15) of the rear body (11) being connected to the inlet flange (15) and the outlet edge (16) of the front body (10) connected to the outlet flange (14) and the inlet flange (15) and the impeller ring (2) have an axial overhang (h) at the pressure edge side (28) of the impeller ring (2), and there is a radial gap (17) and an output bead (14) between them and the finger the impeller (2) has an aadal overhang (m) on the side of the vacuum edge (29) and there is a radial gap (17) between them and in the space defined by the outer surface (25) of the impeller ring (5), the inner wall (26) of the pump housing (1) and planes (et) and (/ 3) at least one overpressure resilient ring collar (19) on the pressure edge side (28) of the ring (5) and at least one underpressure resilient ring collar (5) 18) on the side of the vacuum edge (29) of the ring (5), the planes (<t) and (β) being perpendicular to the longitudinal axis of the pump and the plane (λ) passing through the pressure edge (28) of the ring (5) and plane (β) it extends through the outlet edge (16) of the front body (10) and at least one outlet channel (20) is positioned between the vacuum spring ring (18) and the pressure spring ring (19). Dredging pump according to claim 1, characterized in that the ring (5) consists of a body (27), a vacuum adapter (6) and a positive pressure adapter (7), the negative pressure adapter (6) and the positive pressure adapter (7) being attached to the body (27) of the ring (5) from each side so that they overlap them externally over its entire circumference and axially displaceable therebetween. Dredging pump according to claim 1, characterized in that the body (27) of the ring (5) is provided with replaceable inserts (21) in parts 254 811 adjacent the pressure face (23) of the vanes (4) on the side of the pressure edge (28) of the ring (5). Dredging pump according to claim 1, characterized in that the pressurized elastic annular collars (19) and / or the depressurized elastic annular collars (18) are fixed to the inner wall (26) of the pump body (1) and extend with their opposite edge up to an outer surface (25) of the impeller ring (5). Dredging pump according to claim 1, characterized in that the pressurized flexible ring collars (19) and / or the vacuum flexible ring collars (18) are fixed to the outer surface (25) of the impeller ring (5) and its the opposite edge extends to the inner wall (26) of the pump housing (1). Dredging pump according to claim 1, characterized in that the outer surface f25 of the impeller ring (5) consists of an outer circumferential surface and both end faces of the ring (5). Dredging pump according to claim 1, characterized in that the inlet collar (13), the outlet collar (14), the vacuum adapter (6) and the pressure relief adapter (7) are replaceable.