JP2022020101A - Pump device - Google Patents

Abstract

To provide a pump device capable of obtaining high positional accuracy between a stator and a resin sealing member.SOLUTION: In a pump device 1, a resin sealing member 60 covering a stator 3 is formed with first openings 636 which reach, from a bottom wall part 63 of the resin sealing member 60, at least a part of an outer peripheral surface 311a of an annular part 311 of a stator core 31 and an end surface 311b of the annular part 311. Therefore, when molding the resin sealing member 60, the stator 3 can be positioned in a mold by directly bringing a positioning member into contact with the outer peripheral surface 311a and the end surface 311b of the annular part 311 of the stator core 31 at a position corresponding to the first opening 636. In addition, a side wall part 64 of the resin sealing member 60 is formed with protrusion portions 645 protruding radially outward to a region which overlaps from the radial outer side with the part of the outer peripheral surface 311a of the annular part 311 where the first openings 636 reach.SELECTED DRAWING: Figure 9

Description

The present invention relates to a pump device in which the stator is covered with a resin sealing member.

In the pump device, the impeller arranged in the pump chamber is rotated by a motor. In the stator of the motor, the stator core includes an annular portion and a plurality of salient poles protruding inward in the radial direction from the annular portion, and a coil is wound around the salient poles via an insulator. .. The stator has a resin sealing member formed so as to cover the coil or the like by insert molding. When such resin sealing is performed, the stator is positioned in the mold via the insulator by the positioning member. Therefore, in the resin sealing member, the portion where the positioning member is arranged becomes an opening (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2018-166365

In the technique described in Patent Document 1, since the insulator is made of resin, the insulator may be deformed when the stator is positioned via the insulator by the positioning member. In addition, misalignment may occur between the insulator and the stator core. Therefore, in the configuration in which the stator core is positioned via the insulator when sealing the resin, the positional accuracy between the stator and the resin sealing member may decrease.

In view of the above problems, an object of the present invention is to provide a pump device capable of obtaining high position accuracy between the stator and the resin sealing member.

In order to solve the above problems, the pump device according to the present invention includes a motor and an impeller arranged on one side of the rotation center axis with respect to the motor, and the motor includes a cylindrical stator and a cylindrical stator. A rotor facing the stator in the radial direction and having the impeller connected to one end of the rotation center axis, and a resin seal covering the stator from both sides in the radial direction and both sides in the rotation center axis direction. The stator comprises a member, and the stator includes a stator core having a ring portion and a salient pole extending radially inward from the ring portion, an insulator covering at least the salient pole, and the protrusion via the insulator. The resin encapsulating member comprises a coil wound around a pole, from a bottom wall portion covering the stator from the other side of the rotation center axis to a part of the outer peripheral surface of the annular portion, and the circle. It is characterized by having a first opening that reaches at least one of a part of the end face on the other side of the rotation center axis of the ring portion.

In the present invention, the resin sealing member covering the stator is formed on at least one of the outer peripheral surface of the annular portion of the stator core from the bottom wall portion and a part of the other end surface of the rotation center axis of the annular portion. Since the first opening that has reached the above is provided, when the resin sealing member is molded, the positioning member is brought into direct contact with the stator core at a position corresponding to the first opening, so that the stator is placed in the mold. Can be positioned. Therefore, high positional accuracy can be obtained between the stator and the resin sealing member.

In the present invention, it is possible to adopt an embodiment in which the first opening reaches at least a part of the outer peripheral surface of the annular portion from the bottom wall portion.

In the present invention, it is possible to adopt an embodiment in which the first opening reaches both a part of the outer peripheral surface of the annular portion and a part of the end surface from the bottom wall portion.

In the present invention, among the resin sealing members, the side wall portion that covers the stator from the radial outside is from the outside from the radial direction with respect to a part of the outer peripheral surface of the annular portion reached by the first opening. It is possible to adopt an embodiment in which the overlapping region is provided with a protrusion protruding outward in the radial direction. According to such an aspect, it is possible to secure a sufficient thickness of the side wall portion even at a portion where the first opening portion is provided.

In the present invention, the first opening may be provided at a plurality of locations in the circumferential direction.

In the present invention, it is possible to adopt an embodiment in which the resin sealing member has a second opening that does not reach the outer peripheral surface of the annular portion from the bottom wall portion but reaches a part of the end surface. ..

In the present invention, the insulator is provided with a flange portion that overlaps the annular portion from the other side in the direction of the center axis of rotation, and the outer peripheral surface of the flange portion is provided with a concave portion recessed inward in the radial direction. The first opening and the second opening can each be provided at an angle position where they overlap with the recess.

In the present invention, the second opening may be provided at a plurality of locations in the circumferential direction.

In the present invention, the stator core includes a welded portion connecting portions extending in the circumferential direction, and the resin sealing member can adopt an embodiment in which the welded portion is in contact with the welded portion from the outside in the radial direction.

In the present invention, the resin sealing member can adopt an embodiment having a gate mark on one side of the rotation center axis.

In the present invention, among the resin sealing members, the partition wall portion constituting the bottom portion of the pump chamber in which the impeller is arranged is a cone whose radial outer portion is inclined so as to be located in the pump chamber from the radial inner portion. The resin sealing member may adopt an embodiment having a surface and having the gate mark on the conical surface.

In the present invention, the resin sealing member covering the stator is formed on at least one of the outer peripheral surface of the annular portion of the stator core from the bottom wall portion and a part of the other end surface of the rotation center axis of the annular portion. Since the first opening that has reached the above is provided, when the resin sealing member is molded, the positioning member is brought into direct contact with the stator core at a position corresponding to the first opening, so that the stator is placed in the mold. Can be positioned. Therefore, high positional accuracy can be obtained between the stator and the resin sealing member.

The perspective view which shows one aspect of the pump device to which this invention is applied. The vertical sectional view of the pump device shown in FIG. An exploded perspective view of the pump device shown in FIG. 1. Explanatory drawing of the stator and the like shown in FIG. FIG. 3 is a perspective view of the stator shown in FIG. 2 as viewed from the other side in the direction of the center axis of rotation. An exploded perspective view of the insulator or the like shown in FIG. The bottom view of the stator sealed with the resin sealing member shown in FIG. 4 as viewed from the other side in the direction of the center axis of rotation. FIG. 6 is a cross-sectional view of a stator sealed with the resin sealing member shown in FIG. 4 cut in a direction orthogonal to the rotation center axis. FIG. 4 is a vertical cross-sectional view in which the vicinity of the first opening of the stator sealed with the resin sealing member shown in FIG. 4 is cut along the rotation center axis.

Hereinafter, the pump device according to the embodiment of the present invention will be described with reference to the drawings. In the following description, the rotation center axis L direction means the direction in which the rotation center axis L extends, and the radial direction inside the radial direction and the radial direction inside the radial direction means a radius centered on the rotation center axis L. Means direction.

(overall structure)
FIG. 1 is a perspective view showing one aspect of the pump device 1 to which the present invention is applied. FIG. 2 is a vertical sectional view of the pump device 1 shown in FIG. FIG. 3 is an exploded perspective view of the pump device 1 shown in FIG. In FIGS. 1, 2 and 3, the pump device 1 includes a case 2 having a suction port 21a and a discharge port 22a, a motor 10 having a stator 3 and a rotor 4, and a rotation center axis L direction of the rotor 4. It is provided with an impeller 25 connected to the end of one side L1. The impeller 25 is arranged in a pump chamber 20 provided on one side L1 in the rotation center axis L direction with respect to the motor 10. The stator 3 has a cylindrical shape. The motor 10 includes a resin partition wall member 6 that covers the stator 3, and a round bar-shaped support shaft 7 that rotatably supports the rotor 4. The support shaft 7 is made of metal or ceramic. In the pump device 1 of the present embodiment, the fluid is a liquid, and the pump device 1 is used under conditions in which the ambient temperature and the fluid temperature are likely to change.

The case 2 constitutes a wall surface 23 of L1 on one side of the rotation center axis L direction of the pump chamber 20 and a side wall 29 extending in the circumferential direction. The case 2 includes a suction pipe 21 extending along the rotation center axis L and a discharge pipe 22 extending in a direction orthogonal to the rotation center axis L, and the suction pipe 21 and the discharge pipe 22 are provided. Each has a suction port 21a and a discharge port 22a at the ends. The suction pipe 21 and the suction port 21a are provided concentrically with respect to the rotation center axis L.

In the motor 10, the stator 3 has a stator core 31 and a coil 33 wound around the stator core 31 via an insulator 32. Although detailed description will be described later, the stator core 31 includes an annular portion extending in an annular shape and a plurality of salient poles protruding radially inward from the annular portion. The coil 33 is wound between the radial inner first flange portion and the radial outer second flange portion of the insulator 32 that covers the salient pole. In the present embodiment, the motor 10 is a three-phase motor, and the coil 33 includes a U-phase coil, a V-phase coil, and a W-phase coil.

The rotor 4 includes a cylindrical portion 40 extending radially inward from a position facing the stator 3 toward the pump chamber 20 along the rotation center axis L, and the cylindrical portion 40 is opened in the pump chamber 20. ing. The cylindrical portion 40 is concentric with respect to the suction pipe 21 and the suction port 21a.

A cylindrical magnet 5 is held on the outer peripheral surface of the cylindrical portion 40 so as to face the stator 3 on the inner side in the radial direction. In the present embodiment, the rotor 4 has an annular portion 41 that overlaps the magnet 5 from one side L1 in the rotation center axis L direction and an annular portion that protrudes from the outer edge of the annular portion 41 to the other side L2 in the rotation center axis L direction. A convex portion 42 is formed, and the convex portion 42 covers the end portion of L1 on one side in the rotation center axis L direction of the magnet 5 from the radial outside. Corresponding to such a configuration, the end portion of L1 on one side of the rotation center axis L direction of the magnet 5 is an annular portion 51 overlapping the annular portion 41 inside the convex portion 42 and a radial outer side of the annular portion 51. An annular recess 52 recessed in L2 on the other side of the rotation center axis L direction is formed, and the convex portion 42 overlaps the recess 52. At that time, an adhesive is applied between the magnet 5 and the rotor 4, and the magnet 5 and the rotor 4 are adhered to each other. The magnet 5 is, for example, a neodymium bond magnet. A ring 15 for preventing the magnet 5 from cracking or the like is mounted on the surface of the magnet 5 opposite to the pump chamber 20.

In the rotor 4, a disk-shaped flange portion 45 is formed at the end of L1 on one side L1 of the rotation center axis L direction of the cylindrical portion 40, and the flange portion 45 is formed on one side of the rotation center axis L direction. The disk 26 is connected from L1. A central hole 260 is formed in the center of the disk 26, and the surface of the disk 26 facing the flange portion 45 extends radially outward from the periphery of the central hole 260 while being curved in an arc shape. A plurality of blade portions 261 are formed at equal angular intervals. Each of the plurality of blade portions 261 is formed with a convex portion 262 protruding toward the flange portion 45.

The flange portion 45 is formed with a groove 451 into which the end portion of the blade portion 261 on the flange portion 45 side is fitted, and the bottom portion of the groove portion 451 is formed with a hole 452 into which the convex portion 262 is fitted. Therefore, when the disk 26 is overlapped and fixed on the flange portion 45 so as to fit the convex portion 262 into the hole 452, the flange portion 45 and the disk 26 form an impeller 25 connected to the cylindrical portion 40 of the rotor 4. Will be done. In the present embodiment, the disk 26 is tilted so that the radial outer side is located closer to the flange portion 45 than the radial inner side. Therefore, the distance between the disk 26 and the flange portion 45 is narrower on the radial outer side than on the radial inner side.

A cylindrical radial bearing 11 is held in the rotor 4 radially inside the cylindrical portion 40 by a method such as caulking, and the rotor 4 is rotatably supported by a support shaft 7 via the radial bearing 11. There is. The support shaft 7 is held by the partition wall member 6 as described later.

The partition wall member 6 has a first partition wall portion 61 constituting a bottom wall 24 facing the wall surface 23 of the pump chamber 20, and a second partition wall portion 62 interposed between the stator 3 and the magnet 5. In the present embodiment, the partition wall member 6 is a resin sealing member 60 that covers the stator 3 from both sides in the radial direction and both sides in the rotation center axis L direction, and the stator 3 is insert-molded by polyphenylene sulfide (PPS) or the like. It is a resin part when it is used.

In the present embodiment, a cover 18 is fixed to the resin sealing member 60 from the other side L2 in the rotation center axis L direction, and a circuit for controlling power supply to the coil 33 between the cover 18 and the resin sealing member 60. The substrate 19 provided with the above is arranged. Further, a connector housing 69 is formed on the partition wall member 6. Therefore, when the connector is connected to the connector housing 69 to supply power or the like, the rotor 4 rotates around the rotation center axis L. As a result, when the impeller 25 rotates in the pump chamber 20, the inside of the pump chamber 20 becomes a negative pressure, so that the fluid is sucked into the pump chamber 20 from the suction pipe 21 and discharged from the discharge pipe 22.

(Detailed configuration of the cylindrical portion 40 of the rotor 4 and the like)
In the motor 10 of the present embodiment, the cylindrical portion 40 of the rotor 4 is provided with a through hole 44 between the portion holding the magnet 5 and the impeller 25. Therefore, when the impeller 25 rotates, a part of the fluid flows from the pump chamber 20 into the cylindrical portion 40 of the rotor 4, and then passes through the through hole 44 of the cylindrical portion 40 and again along the bottom wall 24. Flow to. Therefore, the air mixed in the fluid is returned to the pump chamber 20. In this embodiment, the through holes 44 are provided at two positions in the cylindrical portion 40, which are offset by 180 degrees from each other at an angular position.

In the pump chamber 20, the bottom wall 24 formed by the first partition wall portion 61 of the partition wall member 6 is located on the radial outer side of the through hole 44 so that the radial outer portion is located on the side of the pump chamber 20 than the radial inner portion. It has a conical surface 66 tilted toward. Therefore, since the pressure of the fluid from the through hole 44 toward the pump chamber 20 along the bottom wall 24 is high, even if foreign matter is mixed in the fluid, the foreign matter easily flows into the pump chamber 20. Therefore, it is possible to prevent foreign matter from moving from the pump chamber 20 between the magnet 5 held by the rotor 4 and the second partition wall portion 62. Therefore, it is unlikely that a foreign substance is caught between the magnet 5 and the second partition wall portion 62 and the rotation of the rotor 4 is hindered.

Corresponding to such a configuration, the end portion of the first flange portion 322e on the radial inner side of the insulator 32 on the pump chamber 20 side and the end portion of the second flange portion 322f on the radial outer side of the insulator 32 on the pump chamber 20 side. The imaginary line P connecting linearly is inclined along the conical surface 66 with respect to the rotation center axis L. In this embodiment, the angle θ formed by the conical surface 66 and the rotation center axis L is 45 degrees or more and 65 degrees or less.

The bottom wall 24 is provided with an annular outer peripheral region 67 orthogonal to the rotation center axis L on the outer peripheral side of the conical surface 66. In the present embodiment, the conical surface 66 overlaps from an intermediate position in the radial direction of the impeller 25 to a position slightly inside the outer edge, and the annular outer peripheral region 67 is formed so as to project radially outward from the outer edge of the impeller 25. ing. Therefore, the outer peripheral portion of the annular outer peripheral region 67 does not face the impeller 25 but directly overlaps the pump chamber 20. Therefore, on the outer peripheral side of the bottom wall 24, the fluid can smoothly flow out to the pump chamber 20 through the outer peripheral side of the impeller 25.

(Fixed structure of support shaft 7)
As shown in FIG. 2, the partition wall member 6 is formed with a shaft hole 65 into which a first end portion 71 on the side opposite to the pump chamber 20 of the support shaft 7 is fitted. On the other hand, in the case 2, the receiver that faces the second end portion 72 of the support shaft 7 on the pump chamber 20 side on the side of the pump chamber 20 and limits the movable range of the support shaft 7 toward the pump chamber 20 side. The portion 280 is formed.

The shaft hole 65 includes a first hole portion 651 to which the first end portion 71 is fixed, and a second hole portion 652 that communicates with the first hole portion 651 on the opposite side of the pump chamber 20. The portion 652 engages with the first end portion 71 to prevent the support shaft 7 from rotating. In this embodiment, the support shaft 7 is fixed to the partition wall member 6 by press fitting into the first hole portion 651.

In the second hole portion 652, the rotation of the support shaft 7 is prevented by overlapping the flat surface portion formed on the inner peripheral surface of the second hole portion 652 and the flat surface portion formed on the outer peripheral surface of the support shaft 7. For example, both the first end portion 71 and the second hole portion 652 are formed in a D-shaped cross section. Therefore, since the flat surface portion 652a of the second hole portion 652 and the flat surface portion 71a of the first end portion 71 overlap with each other, the second hole portion 652 engages with the first end portion 71 to rotate the support shaft 7. To prevent.

The shaft hole 65 is formed in the bottom wall portion 63 of the partition wall member 6. Further, the first hole portion 651 includes an inner portion of the first cylinder portion 631 projecting from the bottom wall portion 63 toward the pump chamber 20, and the second hole portion 652 is the bottom wall portion 63 with respect to the pump chamber 20. It is provided on the inner portion of the bottomed second cylinder portion 632 that protrudes toward the opposite side. Therefore, it is possible to secure appropriate dimensions in the rotation center axis L direction in each of the first hole portion 651 and the second hole portion 652. Further, the bottom wall portion 63 is provided with a plurality of triangular ribs 635 connected to the outer peripheral surface of the second tubular portion 632. Therefore, even when a large load is applied to the support shaft 7, the second cylinder portion 632 can withstand the applied load.

Here, the opening edge of the shaft hole 65 on the pump chamber 20 side is an inclined surface inclined diagonally inward so that the opening diameter becomes large. Therefore, the support shaft 7 can be easily fitted into the shaft hole 65. Further, the wall thickness of the first cylinder portion 631 is thinner than the wall thickness of the second cylinder portion 632.

The case 2 includes three support portions 27 extending from the inner peripheral surface of the suction pipe 21 to the side of the motor 10. At the end of the support portion 27, a tubular portion 28 in which the support shaft 7 is located inside is formed, and the receiving portion 280 is formed by the bottom portion of L1 on one side in the rotation center axis L direction of the tubular portion 28. .. A gap is provided between the outer peripheral surface of the support shaft 7 and the inner peripheral surface of the tubular portion 28. The receiving portion 280 faces the end surface of the support shaft 7 on the side of the second end portion 72 via the gap G2. Here, the gap G2 between the end surface of the second end portion 72 and the receiving portion 280 is narrower than the dimension G1 in the rotation center axis L direction of the first end portion 71 located inside the second hole portion 652.

An annular thrust bearing 12 is mounted on the second end 72 of the support shaft 7, and the thrust bearing 12 is arranged between the radial bearing 11 and the tubular portion 28. Here, the second end portion 72 of the support shaft 7 and the hole 121 of the thrust bearing 12 are formed in a D-shaped cross section, and the rotation of the thrust bearing 12 and the support shaft 7 is prevented.

As described above, in the pump device 1 of the present embodiment, the first end portion 71 of the support shaft 7 is fixed to the first hole portion 651 of the shaft hole 65 of the partition wall member 6. Therefore, the support shaft 7 can be held by the partition wall member 6 without using insert molding that requires a mold having a complicated structure. Further, in order to prevent the support shaft 7 from rotating by the second hole portion 652 of the shaft hole 65, the support shaft 7 can be held in a stable state by the partition wall member 6. Further, since the gap G2 between the end surface of the second end portion 72 and the receiving portion 280 is narrower than the dimension G1 in the rotation center axis L direction of the first end portion 71 located inside the second hole portion 652, the temperature rises. Then, even when the support shaft 7 is loosened in the first hole portion 651 and the support shaft 7 moves to the receiving portion 280 side, the first end portion 71 does not come off from the second hole portion 652. Therefore, it is possible to prevent the support shaft 7 from rotating. Even when the temperature rises and the fixing of the support shaft 7 in the first hole portion 651 is loosened, if the temperature drops, the fixing of the support shaft 7 in the first hole portion 651 is tightened.

Further, the first hole portion 651 includes an inner portion of the first cylinder portion 631 projecting from the bottom wall portion 63 toward the pump chamber 20, and the second hole portion 652 is the bottom wall portion 63 with respect to the pump chamber 20. It is provided on the inner portion of the bottomed second cylinder portion 632 that protrudes toward the opposite side. Therefore, it is possible to secure appropriate dimensions in the rotation center axis L direction in each of the first hole portion 651 and the second hole portion 652. Further, since the bottom wall portion 63 is provided with a plurality of ribs 635 connected to the outer peripheral surface of the second cylinder portion 632, even when a large load is applied to the support shaft 7, the second cylinder portion receives the load. 632 can withstand.

Further, since the opening edge of the shaft hole 65 on the pump chamber 20 side is an inclined surface, the support shaft 7 can be easily fitted into the shaft hole 65.

(Fixed structure between case 2 and partition wall member 6)
In the pump device 1 of this embodiment, the case 2 and the partition wall member 6 are made of resin. Further, since the support shaft 7 is held in the shaft hole 65 of the partition wall member 6, a gap G2 is secured between the support shaft 7 and the receiving portion 280 of the case 2, and the outer peripheral surface of the support shaft 7 and the cylinder A gap is also secured between the inner peripheral surface of the portion 28 and the inner peripheral surface of the portion 28. Therefore, since a play for relatively moving the case 2 and the partition wall member 6 is secured between the support shaft 7 and the case 2, in the manufacturing process of the pump device 1, the case 2 and the partition wall member 6 are used. It can be fixed by vibration welding.

In vibration welding, the case 2 and the partition wall member 6 are relatively vibrated to perform welding. In the present embodiment, in the partition wall member 6, the end portion of the cylindrical side wall portion 64 that surrounds the stator 3 from the outside in the radial direction on one side L1 in the rotation center axis L direction, and the other end portion of the side wall 29 of the case 2 in the rotation center axis L direction. An annular convex portion is provided on one of the ends of the side L2, and an annular concave portion is provided on the other, and the convex portion is oscillatedly welded in the concave portion. In this embodiment, an annular convex portion 290 is provided at the end of the other side L2 of the side wall 29 in the rotation center axis L direction, and an annular concave portion is provided at the end of the one side L1 of the side wall portion 64 in the rotation center axis L direction. A 640 is provided, and the convex portion 290 is oscillatedly welded in the concave portion 640.

(Structure of stator 3)
FIG. 4 is an explanatory diagram of the stator 3 and the like shown in FIG. FIG. 5 is a perspective view of the stator 3 shown in FIG. 2 as viewed from the other side L2 in the rotation center axis L direction. FIG. 6 is an exploded perspective view of the insulator 32 and the like shown in FIG.

In FIGS. 4, 5 and 6, the stator core 31 includes an annular portion 311 extending in an annular shape and a plurality of salient poles 312 protruding inward in the radial direction from the annular portion 311. The stator core 31 is a laminated core formed by laminating thin magnetic plates made of a magnetic material. On the outer peripheral surface 311a of the annular portion 311, a recess 315 extending in the direction of the rotation center axis L is formed corresponding to the plurality of salient poles 312. The salient poles 312 are formed at equal pitches and are arranged at a constant pitch in the circumferential direction. The salient pole 312 includes a body portion 313 extending in the radial direction and a tip portion 314 extending in an arc shape on both sides in the circumferential direction about the body portion 313.

In the present embodiment, the stator core 31 is formed by bending a member extending linearly into an annular shape and then welding the ends of the annular portions 311 to each other. Therefore, the stator core 31 is provided with a welded portion 310 at one position in the circumferential direction of the annular portion 311 to connect the portions extending in the circumferential direction.

The insulator 32 includes a first member 321 that overlaps the stator core 31 from the other side L2 in the rotation center axis L direction, and a second member 322 that overlaps the stator core 31 from one side L1 in the rotation center axis L direction. Each of the first member 321 and the second member 322 is configured by arranging the resin members 321a and 322a covering each of the plurality of salient poles 312 in the circumferential direction.

Each of the plurality of resin members 321a covers the salient pole 312 from the other side L2 in the rotation center axis L direction and covers the circumference of the body portion 313 from three sides, and the tubular portion forming portion 321b and the radial inner side of the tubular portion forming portion 321b. It includes an inner peripheral side portion 321c bent in the circumferential direction from the end portion, and an outer peripheral side portion 321d bent in the circumferential direction from the radial outer end portion of the tubular portion forming portion 321b. Further, the plurality of resin members 321a each have a first flange portion 321e bent on the other side L2 in the rotation center axis L direction inside the tubular portion forming portion 321b in the radial direction and a radial outer side of the tubular portion forming portion 321b. It has a second flange portion 321f located on the other side L2 in the rotation center axis L direction, and the second flange portion 321f is attached to the annular portion 311 of the stator core 31 from the other side L2 in the rotation center axis L direction. Overlap. Protrusions 321g protruding outward in the radial direction are formed at both ends of the second flange portion 321f in the circumferential direction, and recesses 321h recessed inward in the radial direction are formed between the protrusions 321g.

Each of the plurality of resin members 322a covers the salient pole 312 from one side L1 in the rotation center axis L direction and covers the circumference of the body portion 313 from three sides, and the tubular portion forming portion 322b and the radial inner side of the tubular portion forming portion 322b. It includes an inner peripheral side portion 322c bent in the circumferential direction from the end portion, and an outer peripheral side portion 322d bent in the circumferential direction from the radial outer end portion of the tubular portion forming portion 322b. Further, the plurality of resin members 322a are respectively with respect to the first flange portion 322e bent on one side L1 in the rotation center axis L direction inside the tubular portion forming portion 322b and the radial outside of the tubular portion forming portion 322b. It has a second flange portion 322f located on one side L1 in the rotation center axis L direction, and the second flange portion 322f is attached to the annular portion 311 of the stator core 31 from one side L1 in the rotation center axis L direction. Overlap.

The terminal pin 34 projects from the surface of the second flange portion 321f on the other side L2 in the rotation center axis L direction to the other side L2 in the rotation center axis L direction. Further, on the outer peripheral surface of the second flange portion 322f, a wiring accommodating portion 322i through which the crossover wire 331 extending from the coil 33 passes extends in the circumferential direction. The wiring accommodating portions 322i are provided in three rows in the direction along the rotation center axis L. Therefore, the crossover wire 331 extending from each of the U-phase coil, the V-phase coil, and the W-phase coil provided as the coil 33 can be passed through different wiring accommodating portions 322i. Further, the second flange portion 322f has slits 322j formed at two locations on both sides in the circumferential direction, and the wiring drawn from both ends of the coil 33 is pulled out as a crossover wire 331 from the inside to the outside in the radial direction and connected to the terminal pin 34. can do.

When the first member 321 and the second member 322 of the insulator 32 configured in this way are overlapped with the stator core 31, the tubular portion forming portions 321b and 322b overlap the body portion 313 of the salient pole 312 from four directions. Further, around the body portion 313 of the salient pole 312 between the first flange portion 321e and 322e and the second flange portion 321f and 322f, and between the inner peripheral side portions 321c and 322c and the outer peripheral side portions 321d and 322d. The coil 33 is wound around the insulator 32. In this state, the stator core 31 is in a state where the outer peripheral surface 311a of the annular portion 311 is exposed radially outward from the insulator 32. Further, the outer peripheral portion of the end surface 311c of the end surface 311c of the one side L1 in the rotation center axis L direction of the annular portion 311 of the stator core 31 is exposed from the second flange portion 322f of the insulator 32 toward one L1 in the rotation center axis L direction. become. Further, the outer peripheral portion of the end surface 311b of the other side L2 in the rotation center axis L direction of the annular portion is exposed from the second flange portion 321f of the insulator 32 toward the other side L2 in the rotation center axis L direction, and in particular, the insulator. In the recess 321h of 32, the end surface 311b is exposed toward the other side L2 in the rotation center axis L direction in a wide range.

(Structure of resin sealing member 60)
FIG. 7 is a bottom view of the stator 3 sealed by the resin sealing member 60 shown in FIG. 4 as viewed from the other side L2 in the rotation center axis L direction. FIG. 8 is a cross-sectional view of the stator 3 sealed by the resin sealing member 60 shown in FIG. 4 cut in a direction orthogonal to the rotation center axis L. FIG. 9 is a vertical cross-sectional view of the vicinity of the first opening 636 of the stator 3 sealed by the resin sealing member 60 shown in FIG. 4 cut along the rotation center axis L. In FIG. 7, the opening is shown by a thick line, and the annular portion 311 of the stator core 31 exposed from the opening is shown by a gray area. In this embodiment, as described below, when the stator 3 is insert-molded in the mold and sealed by the resin sealing member 60, the portion of the stator core 31 exposed from the insulator 32 is used in the mold. Positioning of the stator 3 is performed inside. Therefore, in the resin sealing member 60, the following opening is formed in the bottom wall portion 63 that covers the stator 3 from the other side L2 in the rotation center axis L direction.

Specifically, as shown by a thick line in FIG. 7, a plurality of openings 639 are formed in the bottom wall portion 63, and the plurality of openings 639 have an annulus from the bottom wall portion 63 to the stator core 31. A first opening 636 that reaches at least one of a part of the outer peripheral surface 311a of the portion 311 and a part of the end surface 311b of the other side L2 in the rotation center axis L direction of the annular portion 311 is included. In this embodiment, the first opening 636 reaches at least a part of the outer peripheral surface 311a of the annular portion 311 as shown in FIGS. 8 and 9. That is, the first opening 636 reaches a position where it overlaps a part of the outer peripheral surface 311a of the annular portion 311 on the outer side in the radial direction. Therefore, a part of the outer peripheral surface 311a of the annular portion 311 has a gap between the outer peripheral surface 311a and the resin sealing member 60 in the radial direction due to the first opening 636. In this embodiment, the first opening 636 reaches both a part of the outer peripheral surface 311a of the annular portion 311 and a part of the end surface 311b of the annular portion 311. Therefore, a part of the end surface 311b of the annular portion 311 is exposed from the resin sealing member 60 toward the other side L2 in the rotation center axis L direction by the first opening 636. here,
The first openings 636 are provided at a plurality of locations in the circumferential direction. In this embodiment, the first openings 636 are provided at three locations at equal angle intervals.

Further, among the resin sealing members 60, the side wall portion 64 that covers the stator 3 from the radial outside overlaps with a part of the outer peripheral surface 311a of the annular portion 311 reached by the first opening 636 from the radial outside. A protrusion 645 is formed in the region so as to project outward in the radial direction. Therefore, even if the first opening 636 that reaches the outer peripheral surface 311a of the annular portion 311 of the stator core 31 is provided, the wall thickness of the side wall portion 64 can be sufficiently secured on the radial outer side of the first opening 636. can.

In the present embodiment, the plurality of openings 639 further include a second opening 637 that does not reach the outer peripheral surface 311a of the annular portion 311 but reaches the end surface 311b of the annular portion 311. A part of the end surface 311b of the portion 311 is exposed from the resin sealing member 60 toward the other side L2 in the rotation center axis L direction by the second opening 637. The second openings 637 are provided at a plurality of locations in the circumferential direction.

Here, the first opening 636 and the second opening 637 are provided at positions corresponding to the recesses 321h formed in the first member 321 of the insulator 32 shown in FIG. 6 and the like. Therefore, the annular portion 311 of the stator core 31 is exposed to the other side L2 in the rotation center axis L direction with a wide area in the first opening 636 and the second opening 637. However, the first opening 636 and the second opening 637 are provided at positions separated from the welded portion 310 of the stator core 31 in the circumferential direction. Therefore, the resin sealing member 60 covers the welded portion 310 of the stator core 31 and is not exposed from the resin sealing member 60. Therefore, since the welded portion 310 does not come into contact with the fluid flowing through the pump chamber 20, it is possible to suppress the occurrence of rust in the welded portion 310.

In this embodiment, the insulator 32 is not exposed when viewed from the other side L2 in the rotation center axis L direction.

In forming the resin sealing member 60 configured as described above, when the stator 3 is arranged in the mold, the stator 3 is placed in the mold at a position corresponding to the opening 639 by the positioning member to rotate the center axis L. It is supported from the other side L2 in the direction and is positioned in the rotation center axis L direction. Further, at the position corresponding to the first opening 636, the annular portion 311 of the stator core 31 is supported in the radial direction by the positioning member and is positioned in the radial direction. Moreover, at the position corresponding to the second opening 637, it is supported from the other side L2 in the rotation center axis L direction by the pin-shaped member, and is positioned in the rotation center axis L direction.

When sealing the stator 3 inside the mold in this state, a gate is set on one side L1 of the rotation center axis L in the resin sealing member 60. Therefore, the resin sealing member 60 has a gate mark G0 on the surface facing one side L1 of the rotation center axis L. In this embodiment, the gate is set at a position corresponding to the conical surface 66 in the resin sealing member 60. Therefore, the gate mark G0 exists on the conical surface 66. In the resin sealing member 60, a gate may be set in the annular outer peripheral region 67 located on the radial outer side of the conical surface 66 as the surface facing one side L1 of the rotation center axis L. In this case, the annular outer peripheral region may be set. There will be a gate mark at 67. When molding the resin sealing member 60, the terminal block 92 that supports the connector terminal 91 shown in FIG. 7 is also insert-molded together with the stator 3.

(Main action and effect of this form)
As described above, in the pump device 1 of the present embodiment, since the resin sealing member 60 covering the stator 3 is provided with the first opening 636 that reaches the stator core 31 from the bottom wall portion 63, the resin sealing member 60 is resin-sealed. When molding the member 60, the stator 3 can be positioned in the mold by directly contacting the positioning member with the stator core 31 at a position corresponding to the first opening 636. Therefore, higher positional accuracy can be obtained between the stator 3 and the resin sealing member 60 as compared with the structure in which the positioning member is brought into contact with the stator core 31 via the insulator 32. In this embodiment, the stator 3 is brought into contact with the outer peripheral surface 311a and the end surface 311b of the annular portion 311 of the stator core 31 at a position corresponding to the first opening 636 to bring the stator 3 in the radial direction and the rotation center axis L. It is supported in the direction and positioned in the radial direction and the rotation center axis L direction. Therefore, high positional accuracy can be obtained between the stator 3 and the resin sealing member 60.

Further, since the resin sealing member 60 is provided with the second opening 637 that does not reach the outer peripheral surface 311a of the annular portion 311 but reaches the end surface 311b of the annular portion 311, the second opening 637 is provided. By directly contacting the positioning member with the end surface 311b of the annular portion 311 of the stator core 31 at a position corresponding to the above, the stator 3 is supported and positioned in the rotation center axis L direction. Therefore, the position of the stator 3 is less likely to slip due to the pressure when the resin is filled from one side L1 in the rotation center axis L direction. Therefore, high positional accuracy can be obtained between the stator 3 and the resin sealing member 60.

[Other embodiments]
In the above embodiment, the first opening 636 is a part of the outer peripheral surface 311a of the annular portion 311 of the stator core 31 from the bottom wall portion 63, and the end surface 311b of the other side L2 of the annular portion 311 in the rotation center axis L direction. The first opening 636 reaches a part of the outer peripheral surface 311a of the annular portion 311 of the stator core 31 from the bottom wall portion 63, and reaches the rotation center axis L direction of the annular portion 311. It may be an embodiment that does not reach the end surface 311b of the other side L2. Further, the first opening 636 reaches the end surface 311b of the other side L2 in the rotation center axis L direction of the annular portion 311 from the bottom wall portion 63, and reaches a part of the outer peripheral surface 311a of the annular portion 311 of the stator core 31. It may be a mode that has not been reached.

1 ... pump device, 2 ... case, 3 ... stator, 4 ... rotor, 5 ... magnet, 6 ... partition member, 7 ... support shaft, 10 ... motor, 20 ... pump chamber, 25 ... impeller, 31 ... stator core, 32 ... Insulator, 33 ... Coil, 60 ... Resin sealing member, 61 ... First partition, 62 ... Second partition, 63 ... Bottom wall, 64 ... Side wall, 65 ... Shaft hole, 66 ... Conical surface, 67 ... Circular outer peripheral region, 311a ... outer peripheral surface, 311b ... end surface, 312 ... salient pole, 313 ... body, 314 ... tip, 321 ... first member, 321a, 322a ... resin member, 321e, 322e ... first flange, 321f, 322f ... 2nd flange, 321h ... recess, 322 ... 2nd member, 636 ... 1st opening, 637 ... 2nd opening, 639 ... opening, G0 ... gate mark, L ... rotation center axis

Claims (11)

A motor and an impeller arranged on one side of the rotation center axis with respect to the motor are provided.
The motor has a cylindrical stator, a rotor facing the stator radially inside, and an impeller connected to one end of the rotation center axis, and the stator on both sides in the radial direction and the rotation. With a resin sealing member that covers from both sides in the central axis direction,
The stator is wound around the salient pole via an annular portion, a stator core having a salient pole extending radially inward from the annular portion, an insulator covering at least the salient pole, and the insulator. With a coil,
The resin sealing member includes a part of the outer peripheral surface of the annular portion from the bottom wall portion that covers the stator from the other side of the rotation center axis, and the end surface of the annular portion on the other side of the rotation center axis. A pumping apparatus comprising a first opening that reaches at least one of a portion. In the pump device according to claim 1,
The pump device is characterized in that the first opening reaches at least a part of the outer peripheral surface of the annular portion from the bottom wall portion. In the pump device according to claim 2,
The pump device is characterized in that the first opening reaches both a part of the outer peripheral surface of the annular portion and a part of the end surface from the bottom wall portion. In the pump device according to claim 2 or 3.
Among the resin sealing members, the side wall portion that covers the stator from the outside in the radial direction has a diameter in a region overlapping from the outside in the radial direction with respect to a part of the outer peripheral surface of the annular portion reached by the first opening. A pumping device characterized by having a protrusion protruding outward in the direction. In the pump device according to any one of claims 1 to 4.
The pump device is characterized in that the first openings are provided at a plurality of locations in the circumferential direction. In the pump device according to any one of claims 1 to 5.
The resin sealing member is a pump device having a second opening that does not reach the outer peripheral surface of the annular portion from the bottom wall portion but reaches a part of the end surface. In the pump device according to claim 6,
The insulator is provided with a flange portion that overlaps the annular portion from the other side in the direction of the center axis of rotation.
On the outer peripheral surface of the flange portion, a concave portion recessed inward in the radial direction is provided.
A pump device characterized in that the first opening and the second opening are each provided at positions overlapping with the recess. In the pump device according to claim 6 or 7.
The second opening is a pump device characterized in that it is provided at a plurality of locations in the circumferential direction. In the pump device according to any one of claims 1 to 8.
The stator core includes a welded portion that connects portions extending in the circumferential direction.
The resin sealing member is a pump device characterized by covering the welded portion. In the pump device according to any one of claims 1 to 9.
The resin sealing member is a pump device having a gate mark on one side of the rotation center axis. In the pump device according to claim 10,
Among the resin sealing members, the partition wall portion constituting the bottom portion of the pump chamber in which the impeller is arranged has a conical surface inclined so that the radial outer portion is located in the pump chamber from the radial inner portion.
The resin sealing member is a pump device having the gate mark on the conical surface.

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