JP2010014048A - Impeller for centrifugal pump - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve both improvement of foreign matter passage performance by expanding the diameter of a flow passage and reduction in power by contracting the diameter of an impeller while obtaining mechanical balance and hydraulic balance by mounting a balance weight 64, in the impeller (impeller body 61) for a centrifugal pump. <P>SOLUTION: The balance weight 64 has a vertical shape having the height in a cylinder axis direction set larger than the thickness in the radial direction. The vertical balance weight 64 is embedded in the peripheral edge part of the cylindrical impeller body 61. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an impeller for a centrifugal pump.

  Conventionally, a centrifugal pump has been used as a pump suitable for transporting sewage, etc., and among the impellers that this centrifugal pump has, blades that do not easily clog even sewage containing solids such as foreign substances As a vehicle, there is known a non-clog type impeller in which a flow path connecting an inlet opening on one end surface and an outlet opening on a peripheral surface is formed (see, for example, Patent Document 1).

Since the non-clog type impeller is a single blade, the shape becomes non-axisymmetric with respect to the rotation axis. Therefore, the impeller disclosed in Patent Document 1 obtains a static balance when stationary or a dynamic balance when rotating in the air in the air (hereinafter collectively referred to as mechanical balance). In order to obtain a balance (hydraulic balance) when the impeller is rotated in water, a balance weight is attached. Specifically, in the impeller disclosed in Patent Document 1, a flat shape extending in the radial direction on each of the upper surface of the upper flange portion and the lower surface of the lower flange portion protruding outward in the radial direction over the entire circumference. The balance weight is attached with bolts.
Japanese Patent Laid-Open No. 10-238495

  By the way, from the viewpoint of reducing the power of the submersible pump, it is desirable to reduce the diameter of the impeller. On the other hand, if the passing particle size of the impeller (the maximum diameter of the sphere that can pass through the flow path) is increased to increase the foreign substance permeability, the diameter of the flow path formed in the impeller is increased. Must. Therefore, if it is going to achieve these together, the protrusion width of the radial direction of the flange part in an impeller must be made small.

  However, if the protrusion width of the flange portion is reduced in this way, especially in the lower flange portion, there is almost no area on the lower surface, so a sufficient balance weight can be attached to this portion. The inconvenience of being unable to do so occurs.

  This invention is made | formed in view of this point, The place made into the objective is obtaining mechanical balance and hydraulic balance by attaching a balance weight in the impeller (impeller main body) for centrifugal pumps. On the other hand, it is to achieve both the improvement of the passage of foreign substances by increasing the diameter of the flow path and the reduction of power by reducing the diameter of the impeller.

  According to one aspect of the present invention, an impeller for a centrifugal pump has a substantially cylindrical shape including one end surface and the other end surface facing the cylinder axis direction, and a peripheral surface between the one end surface and the other end surface. An impeller body in which an internal flow path connecting an inlet opening in the one end surface and an outlet opening in the peripheral surface is formed, and a balance weight embedded in the impeller body, the balance weight is The cylindrical shaft has a vertical shape whose height in the axial direction is larger than the thickness in the radial direction, and the vertical balance weight is embedded in the peripheral portion of the cylindrical impeller body. Yes.

  According to this configuration, by making the shape of the balance weight vertical, it is possible to embed the balance weight also in the peripheral portion of the impeller body that is relatively thin in the radial direction. Then, by embedding the balance weight in the impeller body, for example, it is not necessary to attach the balance weight to the flange portion. As a result, it is possible to simultaneously increase the flow path diameter and reduce the impeller diameter while obtaining mechanical balance and hydraulic balance by embedding the balance weight.

  One end of the impeller body may be a relatively thin wear ring provided to surround the inlet, and the balance weight may be embedded in the wear ring. .

  Since the flange portion of the impeller body is located in the spiral chamber of the casing, for example, a balance weight can be attached to the outer peripheral surface thereof. On the other hand, since the wear ring part faces the liner ring of the casing with a slight gap therebetween, for example, a balance weight cannot be attached to the outer peripheral surface thereof. Therefore, the configuration in which the balance weight is embedded is a particularly effective configuration when embedded in the wear ring portion.

  The balance weight embedded in the wear ring part has a lower end surface exposed at one end surface of the impeller body, and the balance weight is recessed from a through-hole penetrating in the thickness direction or the lower end surface. A notch is formed, and when the impeller body is molded, the balance weight through-hole or the notch is filled with resin, whereby the balance weight retaining portion is configured. It is good also as.

  Since the lower end surface of the balance weight is exposed at one end surface of the impeller body, it is ensured that such a drop-off is provided by providing a retaining part where the balance weight may fall out during use of the impeller. Is prevented. In addition, the balance weight can be prevented from coming off by a simple method in which through holes or notches are provided in the balance weight and molding is performed.

  The balance weight is formed with a plurality of positioning holes into which positioning pins are inserted, and the balance weight is held by the positioning pins inserted into the positioning holes at the time of molding, It is good also as being located in the predetermined position in a shaping | molding die.

  By doing so, the balance weight can be accurately positioned at a predetermined position in the mold, and the balance weight can be surely embedded in the peripheral portion of the impeller body.

  As described above, according to the present invention, by making the shape of the balance weight vertical, the balance weight can be embedded in the peripheral portion of the impeller body that is relatively thin in the radial direction. While obtaining a mechanical balance and a hydraulic balance, it is possible to increase the flow path diameter and reduce the impeller diameter. As a result, it is possible to achieve both improved foreign substance passage and reduced power.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature, and is not intended to limit the present invention, its application, or its use.

  FIG. 1 shows a submersible pump 1 equipped with an impeller according to an embodiment of the present invention. The submersible pump 1 includes a pump unit 21 having an impeller 6 and a motor unit 22 having a motor 3 that drives the impeller 6. The submersible pump 1 is configured such that the pump unit 21 and the motor unit 22 are arranged side by side in the vertical direction by disposing the pump unit 21 on the lower side of the oil casing 23 and the motor unit 22 on the upper side. ing. The submersible pump 1 is a lightweight type in which a later-described head cover 34 and pump casing 4 are formed of a predetermined resin material.

  The motor unit 22 includes the motor 3 including a stator 31 and a rotor 32, a stator casing 33 that covers the stator 31 of the motor 3, and a head cover 34 that is attached to the upper end of the stator casing 33. The rotation shaft 35 of the motor 3 is arranged extending in the vertical direction.

  The stator casing 33 is formed in a substantially cylindrical shape with openings at both ends. The upper end opening of the stator casing 33 is closed by a motor cover 36, and a bearing 35 a that rotatably supports the upper end portion of the rotating shaft 35 is attached to the lower surface of the motor cover 36.

  The head cover 34 is attached to the upper end of the stator casing 33. The head cover 34 includes an upper wall and a peripheral wall that extends downward from the peripheral edge of the upper wall and is fixed to the upper end of the stator casing 33, and has a cross-sectional shape formed in an inverted U shape. As a result, the head cover 34 forms an accommodation space 34 a for accommodating various electrical components together with the motor cover 36. A cable boot through which a power supply cable for supplying power to the motor 3 is inserted is attached to the upper wall of the head cover 34, and a handle 34b is attached to the center of the upper surface thereof.

  The head cover 34 is fixed to the oil casing 23 by a plurality of bolts 37 (only one is shown in the figure) arranged at predetermined intervals in the circumferential direction. In other words, the bolt 37 that has passed through the through hole formed in the peripheral edge of the head cover 34 passes through the motor cover 36 and extends downward along the inner peripheral surface of the stator casing 33, so that the peripheral edge of the oil casing 23. It is screwed to the part. Thus, in this submersible pump 1, the head cover 34, the stator casing 33, and the motor cover 36 are fixed to the oil casing 23 at once by the long bolts 37 extending in the vertical direction. In this submersible pump 1, the number of parts and the number of assembling steps are reduced.

  The oil casing 23 is attached to the lower end of the stator casing 33, and the lower end opening of the stator casing 33 is closed by the oil casing 23.

  The oil casing 23 is a casing that forms an oil chamber 53 filled with lubricating oil together with the pump casing 4 by attaching the pump casing 4 to the lower side of the oil casing 23. A through hole to be inserted is formed, and a bearing 35b for rotatably supporting an intermediate portion of the rotating shaft 35 is attached to the upper surface thereof.

  In the oil chamber 53 defined by the oil casing 23 and the pump casing 4, the rotary shaft 35 is sealed with a mechanical seal 51, and an annular wall 52 that surrounds substantially the entire outer periphery of the mechanical seal 51 is provided. It has been.

  The pump unit 21 includes the impeller 6 attached to the lower end of the rotation shaft 35 of the motor 3 and the pump casing 4.

  The submersible pump 1 is a centrifugal pump, and the pump casing 4 is integrated with an upper first pump casing 41 and a lower second pump casing 42 which form an oil chamber 53 together with the oil casing 23 by welding. Is made up of. Thus, by integrating the first pump casing 41 and the second pump casing 42 by welding, for example, a flange that is required when two pump casings are integrated by means of fastening means of bolts and nuts becomes unnecessary. Miniaturization of the submersible pump 1 is realized.

  A through hole into which the rotary shaft 35 is inserted is formed in the upper part of the pump casing 4, and a vortex chamber 43 for accommodating the impeller 6 is formed therein.

  Moreover, the lower part of the pump casing 4 is opened downward, and a liner ring 44 having an opening 44a for supporting the wear ring part 692 which is the lower end part of the impeller 6 is attached to the opening. It has been.

  On the other hand, a discharge portion 45 that protrudes laterally and curves upward is integrally formed on the side portion of the pump casing 4. The discharge part 45 communicates with the spiral chamber 43 and is formed with a discharge port 45a that opens upward. The discharge port 45a is connected to a discharge pipe (not shown).

  Then, four legs 46 (only three are shown in FIG. 1) extending downward are arranged in a predetermined arrangement at the lower part of the pump casing 4. It is fixedly attached to 7.

  The stand 7 includes a main body portion 71 made of synthetic resin and a rubber cover 72 that covers the lower side of the main body portion 71. The lower end of each leg portion 46 is formed on the main body portion 71. An insertion portion 73 that is inserted and fixed with a screw protrudes upward and is integrally formed. A damping rubber or damping steel plate 74 is interposed between the lower surface of each leg portion 46 and the insertion portion 73, whereby the stand 7 is installed at the position where the submersible pump 1 is installed by the cover 72. Both the function of preventing the shift and the vibration damping function when the submersible pump 1 is driven by the vibration damping rubber or the vibration damping steel plate 74 are achieved.

  In this embodiment, the impeller 6 is a non-clog type impeller having a substantially cylindrical shape, as shown in FIGS. 2 to 5, and is rotated so that the cylindrical shaft and the rotation shaft 35 are coaxial. It is fixed to the lower end of the shaft 35 (see FIG. 1). The impeller 6 includes an impeller body 61 and a lid 62 attached to the upper end surface of the impeller body 61. In addition, the impeller 6 includes an upper balance weight 63 and a lower balance weight 64 in order to obtain the mechanical balance and hydraulic balance. As will be described in detail later, as shown in FIG. 5, the upper balance weight 63 is disposed and fixed between the impeller body 61 and the lid body 62, and the lower balance weight 64 is a wear ring portion of the impeller body 61. 692 is buried.

  The impeller body 61 has a substantially cylindrical shape, and an inlet 601 that opens downward is formed at a lower end surface of the impeller body 61, while an opening toward the side is formed at a predetermined position on the peripheral surface. An outlet 602 is formed. Thus, an internal channel 603 extending in the cylinder axis direction is formed inside the impeller 6, and the inlet 601 and the outlet 602 are connected to each other by the internal channel 603.

  An outer flow path 604 that is recessed inward in the radial direction is formed on the outer peripheral surface of the impeller body 61. The external flow path 604 is not a flow path extending in the cylinder axis direction, and the flow path center is located on an orthogonal plane orthogonal to the cylinder axis of the impeller body 61. The external flow path 604 is continuous with the downstream side of the internal flow path 603 at the outlet 602, and circulates over the length of one round of the impeller 6.

  This external flow path 604 is partitioned by blades 605. This blade 605 is a so-called radial flow type single blade (centrifugal blade), and the centrifugal blade 605 pressurizes the water in the external flow path 604 and discharges it to the outer peripheral side (radially outward).

  In the impeller body 61, a first flange portion 681 protruding outward in the radial direction is formed over the entire circumference above the external flow path 604. Further, a second flange portion 682 is formed below the external flow path 604 so as to project outward in the radial direction over the entire circumference. The second flange portion 682 partitions the lower portion of the impeller 6 where the inlet 601 is formed from the upper portion where the outlet 602 is formed. In other words, the impeller 6 is a closed type impeller in which the inlet 601 and the outlet 602 are partitioned by the second flange portion 682.

  Thus, the shaft in which the mounting hole in which the rotation shaft 35 of the motor 3 is inserted and fixed is formed at the center of the upper end surface of the impeller body 61 that is above the first flange portion 681. A support portion 691 is formed to protrude upward. The shaft support portion 691 is made of a predetermined metal material. Further, a wear ring portion 692 inserted into the opening 44a of the pump casing 4 is formed on the impeller body 61 below the second flange portion 682 so as to protrude downward.

  Here, from the viewpoint of reducing the power of the submersible pump 1, the impeller body 61 is set such that the diameters of the first and second flange portions 681 and 682 are small so that the diameter is as small as possible. As a result, as shown in FIGS. 3 and 5, the design has almost no step between the second flange portion 682 and the wear ring portion 692. For example, the diameters of the first and second flange portions 681 and 682 may be further reduced so that this step is eliminated. Conversely, the step between the second flange portion 682 and the wear ring portion 692 may be eliminated by enlarging the diameter of the wear ring portion 692 so that the diameter of the inlet 601 is increased.

  The impeller body 61 is made of synthetic resin, and has a substantially constant thickness to prevent sink marks during molding, as shown in FIGS. A recessed portion 611 that is recessed is formed. As shown in FIG. 6, the recessed portion 611 extends in the circumferential direction by about ¾ turn counterclockwise from the side where the outlet 602 opens (upper side in FIG. 6). Further, as shown in FIG. 5, the recessed portion 611 has a relatively shallow depth on the opening side of the outlet 602 (right side in FIG. 7), and is opposite to the opening side of the outlet 602 (left side in FIG. 7). ) Is configured to be relatively deep.

  Further, a reinforcing rib 612 is formed at the upper end portion of the impeller body 61 so as to connect the shaft support portion 691 and the peripheral portion of the impeller body 61 to each other by extending in the radial direction. In this embodiment, in the impeller body 61 shown in FIG. 6, three reinforcing ribs 612 are formed in the upper half region corresponding to the opening side of the outlet 602 with a predetermined angle therebetween, One reinforcing rib 612 is formed in the lower half region corresponding to the side opposite to the opening side of the outlet 602. Then, three of the total four reinforcing ribs 612 are arranged in the recessed portion 611.

  Each of the three reinforcing ribs 612 disposed on the opening side of the outlet 602 also serves as a placement portion on which the upper balance weight 63 is placed, as shown in FIG. That is, the upper end surface of each reinforcing rib 612 functions as a mounting surface 614 on which the upper balance weight 63 is mounted. Furthermore, a boss portion 613 for fixing the upper balance weight 63 is formed at a substantially central position in the radial direction of each reinforcing rib 612.

  As shown in FIGS. 9 and 10, the boss portion 613 is a portion having a diameter larger than the width of the reinforcing rib 612 and having a circular shape in a plan view. A pin hole 615 extending in the direction is formed. Further, on the outer peripheral surface of the boss portion 613, three protrusions 616 protruding outward in the radial direction are formed integrally with the boss portion 613 at equal intervals in the circumferential direction.

  As shown in FIG. 11, the upper balance weight 63 made of a predetermined metal material has a substantially sector shape in which an annular plate member having a predetermined plate thickness is cut out by a predetermined angle range. The upper balance weight 63 has a horizontal shape in which the radial width is larger than the thickness in the cylinder axis direction (vertical direction). As shown in FIG. 6, the upper balance weight 63 is disposed between the shaft support portion 691 and the peripheral portion of the impeller body 61, so that the inner diameter thereof is larger than the diameter of the shaft support portion 691. On the other hand, the outer diameter is set smaller than the diameter of the peripheral edge of the impeller body 61. The shape of the upper balance weight 63 is not particularly limited, and is appropriately set so as to ensure a necessary weight under the restriction that the upper balance weight 63 is disposed between the impeller body 61 and the lid body 62. That's fine.

  In the upper balance weight 63, three holes 631 are formed penetrating in the thickness direction so as to correspond to the three boss portions 613, respectively. Each hole is an outer fitting hole 631 fitted to the boss portion 613. As shown in FIG. 9, the hole diameter is larger than the diameter of the boss portion 613 and a circle connecting the tips of the protrusions 616. The diameter is set smaller than the diameter.

  Then, the upper balance weight 63 is arranged on the mounting surface 614 of the reinforcing rib 612 so that each outer fitting hole 631 is fitted to the boss portion 613 as shown in an enlarged view in FIGS. Accordingly, the upper balance weight 63 is positioned at a predetermined position on the opening side of the outlet 602 on the upper end surface of the impeller body 61. Here, the outer fitting hole 631 of the upper balance weight 63 is set to have a diameter that is larger than the diameter of the boss portion 613 and smaller than the diameter of the circle connecting the tips of the protrusions 616. When the part is crushed, the outer fitting hole is fitted onto the boss portion 613. Thereby, the play of the upper balance weight 63 can be eliminated.

  As shown in FIGS. 7 and 8, the lid body 62 has a disk shape, and an insertion hole 621 into which the shaft support portion 691 of the impeller body 61 is inserted is formed at the center thereof. The lid 62 is made of a synthetic resin, and the surface side is configured to be a flat surface, while the peripheral edge has a side corresponding to the opening of the outlet 602 and a side opposite to the side across the cylinder shaft. In each case, two elastic engagement claws 622 are integrally formed with the lid body 62 at a predetermined interval in the circumferential direction. Each elastic engagement claw 622 is a claw that engages with an engagement groove 683 formed on the peripheral edge portion of the upper end portion of the impeller body 61, and the elastic engagement claw 622 and the engagement groove 683 allow The engaging means for attaching and fixing the lid 62 to the impeller body 61 is configured.

  Three fitting pins 623 are formed on the back surface of the lid 62 so as to protrude from the back surface at positions corresponding to the boss portions 613 of the impeller body 61. As shown in FIG. 10, each fitting pin 623 is fitted into a pin hole 615 formed in each boss portion 613 when the lid 62 is attached to the impeller body 61. Thus, in addition to the engagement between the elastic engagement claw 622 and the engagement groove 683, the lid body 62 is fitted into the pin hole 615 with respect to the impeller body 61. It will be fixed and fixed more stably.

  A pressing portion 624 for pressing the upper balance weight 63 is further formed on the back surface of the lid 62 so as to protrude from the back surface. The holding portion 624 is formed in an annular shape so as to surround each fitting pin 623, and as a result, when the lid 62 is attached and fixed to the impeller body 61 as shown in FIG. 10, The lower surface presses the upper surface of the upper balance weight 63 downward in the peripheral portion of the boss portion 613. Thus, the upper balance weight 63 is held between the lid body 62 and the impeller body 61.

  The lid 62 is also formed with two through holes 625 on the opening side of the outlet 602 and on the opposite side. This through hole is an air vent hole 625 for extracting air from the recessed portion 611 of the impeller body 61 and filling the recessed portion 611 with water. An air vent hole may also be formed in the upper balance weight 63. In this case, the air vent hole is preferably formed at the same position as the air vent hole 625 formed in the lid body 62.

  Thus, by providing the air vent hole 625 in the lid 62 and filling the recessed portion 611 with water, the mechanical balance of the impeller 6 is caused by the air remaining in the recessed portion 611. It can be prevented from collapsing, and vibration can be prevented from occurring when the impeller 6 is driven.

  As shown in FIGS. 3 and 4, the lower balance weight 64 is embedded in the wear ring portion 692 on the opening side of the outlet 602 of the impeller body 61.

  As shown in FIG. 12 and the like, the lower balance weight 64 made of a predetermined metal material is a plate piece curved in an arc shape, and is a vertical type whose height in the cylinder axis direction is larger than its radial thickness. It has a shape. Then, as shown in FIG. 4, the lower balance weight 64 is embedded in the wear ring portion 692 so that the lower end surface thereof is exposed to the lower end surface of the impeller body 61.

  Two through holes 641 are formed at predetermined positions in the lower balance weight 64, and each through hole 641 functions as a positioning hole into which the positioning pin 8 of the molding die is inserted. Further, a notch 642 is formed at the center position at the lower end of the lower balance weight 64. When the impeller body 61 is molded by the notch 642, the resin is filled in the notch 642, and as a result, as shown in FIG. The retaining portion 694 that crosses in the thickness direction is formed.

  Next, the manufacturing procedure of the impeller body 61 will be briefly described. First, the shaft support portion 691 and the lower balance weight 64 are respectively arranged at predetermined positions in a mold (not shown). At this time, as shown in FIG. 12, the lower balance weight 64 has its circumferential position and its inclination defined by the two positioning pins 8. Further, the positioning pin 8 has a small-diameter portion 81 on the distal end side and a large-diameter portion 82 on the proximal end side, and the radial position of the lower balance weight 64 is also defined at the step positions having different diameters. It will be. Thus, since the lower balance weight 64 can be accurately positioned at a predetermined position in the mold, the lower balance weight 64 can be reliably embedded in the thin wear ring 692 in the impeller body 61.

  Thus, the impeller body 61 is formed by well-known resin molding. As shown in FIGS. 2 and 3, a hole 693 formed by the positioning pin 8 is formed in the wear ring 692 of the impeller body 61 after the molding.

  Next, a separately prepared upper balance weight 63 is attached to the upper end surface of the impeller body 61 after molding. As described above, the upper balance weight 63 causes the protrusions 616 of the boss portion 613 to be crushed so that the outer fitting holes 631 of the upper balance weight 63 are fitted to the boss portion 613.

  Thereafter, a separately formed lid 62 is attached to the impeller body 61. At this time, the fitting pin 623 of the lid body 62 is fitted into the pin hole 615 of the impeller body 61 and the elastic engagement claw 622 of the lid body 62 is elastically deformed, so that the impeller body 61 is engaged. Engages with the groove 683. In this way, the lid 62 is attached and fixed to the impeller body 61, and at the same time, the pressing portion 624 of the lid 62 presses the upper balance weight 63, thereby the impeller body of the upper balance weight 63. The attachment to 61 is also completed.

  Thus, the impeller 6 of this configuration does not use fastening means such as bolts for fixing the lid 62, and the lid is formed by engaging the elastic engagement claw 622 with the engagement groove 683. The body 62 is attached and fixed to the impeller body 61. For this reason, a tool or the like is not required for the assembling work, the assembling of the impeller 6 is simplified, and the upper balance weight 63 is fixed simultaneously with the attachment of the lid 62, and therefore the assembling work of the impeller 6 is performed. Can be further facilitated.

  Here, since the elastic engagement claw 622 is provided on the lid 62, the engagement groove 683 that opens outward is provided on the peripheral edge of the impeller body 61. In this state, the engaging means does not protrude from the surface of the lid 62, and the upper end surface of the impeller 6 can be surely made flat. This is advantageous in reducing power loss. In addition, while providing the engaging groove in the lid 62, the impeller body 61 may be provided with an engaging claw. Further, the engagement means for engaging the lid 62 and the impeller body 61 is not limited to the combination of the elastic engagement claw 622 and the engagement groove 683, and appropriate engagement means may be adopted. Is possible.

  Further, the peripheral edge portion of the lid body 62 is fixed to the impeller body 61 by the elastic engagement claw 622 and the engagement groove 683, while the fitting pin 623 provided on the lid body 62 is attached to the impeller body 61. By fitting inside the pin hole 615, the central portion of the lid body 62 in the radial direction can be fixed to the impeller body 61. As a result, the central portion of the lid body 62 in the radial direction is prevented from floating with respect to the impeller body 61.

  Further, by fitting the outer fitting holes 631 of the upper balance weight 63 to the boss portion 613 of the impeller body 61, the upper balance weight 63 is accurately placed at a predetermined position with respect to the impeller body 61. In addition to being positioned, it is possible to prevent the upper balance weight 63 from being loose.

  Thus, the strength of the impeller body 61 itself is improved by the reinforcing rib 612, and the boss portion 613 for fixing the upper balance weight 63 and the lid body is formed integrally with the reinforcing rib 612 so that the boss portion The rigidity of 613 is also improved, and the upper balance weight 63 and the lid 62 can be more stably fixed to the impeller body 61.

  On the other hand, unlike the upper balance weight 63, the lower balance weight 64 has a vertical shape, and therefore can be embedded in a thin wear ring 692 in the radial direction.

  Thus, by embedding the lower balance weight 64 in the impeller body 61, there is no need to attach a balance weight to the second flange portion 682, and the diameter of the inlet 601 of the impeller 6 is made as large as possible. The power of the submersible pump 1 can be reduced by reducing the diameter of the impeller 6 by reducing the diameter of the first and second flange portions 681 and 682 as much as possible while ensuring the foreign substance passage characteristics. it can.

  Further, the lower balance weight 64 embedded in the wear ring portion 692 has a lower end surface exposed at the lower end surface of the impeller body 61, so that the lower balance weight 64 may fall off during use of the impeller 6. On the other hand, the notch 642 is formed at the lower end of the lower balance weight 64 to form the retaining portion 694, so that the lower balance weight 64 is reliably prevented from falling off. In the present embodiment, the retaining portion 694 is configured by forming a notch 642 at the lower end of the lower balance weight 64. However, for example, in the middle of the lower balance weight 64 in the height direction, in the thickness direction. It is also possible to form a resin retaining portion that crosses the lower balance weight 64 in the thickness direction by forming a through hole that penetrates. Alternatively, the entire lower balance weight 64 may be embedded in the impeller body 61 so that the lower end of the lower balance weight 64 is not exposed. In such a case, it is not necessary to configure a retaining portion.

  In the above-described embodiment, the lower balance weight 64 is embedded in the wear ring 692. However, for example, when securing the necessary weight, the lower balance weight 64 is further increased in height. The upper end portion may be positioned at a position corresponding to the second flange portion 682.

  Further, the balance weight 64 is not limited to being embedded in the wear ring portion 692 but may be embedded in an appropriate portion of the peripheral portion of the impeller body 61.

  Furthermore, the impeller according to the present invention is not limited to a synthetic resin impeller.

  As described above, according to the present invention, the balance weight is embedded in the impeller body, thereby obtaining a mechanical balance and a hydraulic balance, while improving the passage of foreign substances and increasing the impeller diameter by increasing the flow path diameter. Since both power reduction by reduction can be achieved, it is useful as an impeller for a centrifugal pump.

It is sectional drawing of the submersible pump provided with the impeller for centrifugal pumps concerning embodiment of this invention. It is a perspective view of an impeller. It is a front view of an impeller. It is a bottom view of an impeller. It is VV sectional drawing of FIG. It is a top view of an impeller body in the state where a lid was removed. It is a reverse view of a cover body. It is VIII-VIII sectional drawing of FIG. It is a top view which expands and shows the boss | hub part vicinity of an impeller main body. It is sectional drawing which expands and shows the boss | hub part vicinity of an impeller main body. It is a perspective view of an upper balance weight. It is a perspective view of a lower balance weight.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Submersible pump 6 Impeller 601 Inlet 602 Outlet 603 Internal flow path 61 Impeller main body 64 Lower balance weight 641 Positioning hole 642 Notch 692 Wear ring part 694 Retaining part 8 Positioning pin

Claims (4)

It has a substantially cylindrical shape including one end surface and the other end surface facing in the cylinder axis direction, and a peripheral surface between the one end surface and the other end surface, and an inlet opening on the one end surface and an outlet opening on the peripheral surface An impeller body in which an internal flow path is formed, and
A balance weight embedded in the impeller body,
The balance weight has a vertical shape whose height in the cylinder axis direction is larger than the thickness in the radial direction, and the vertical balance weight is a peripheral portion of the cylindrical impeller body. Impeller for centrifugal pumps embedded against. The impeller for a centrifugal pump according to claim 1,
One end of the impeller body is a relatively thin wear ring provided to surround the inlet,
The balance weight is an impeller for a centrifugal pump embedded in the wear ring portion. In the impeller for centrifugal pumps according to claim 2,
The balance weight embedded in the wear ring part has a lower end surface exposed at one end surface of the impeller body, and the balance weight is recessed from a through-hole penetrating in the thickness direction or the lower end surface. A notch is formed,
An impeller for a centrifugal pump in which a retaining portion for the balance weight is configured by filling a resin in a through hole or a notch of the balance weight when the impeller body is molded. In the impeller for centrifugal pumps according to any one of claims 1 to 3,
A plurality of positioning holes into which positioning pins are respectively inserted are formed in the balance weight,
The balance weight is held by a positioning pin inserted into the positioning hole at the time of molding, so that the balance weight is positioned at a predetermined position in the mold.

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