JP2018031330A - Electric fluid pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a novel electric fluid pump which can suppress the vibration of a slide bearing to a radial direction by a simple constitution.SOLUTION: Lubrication grooves 42A and 42B formed at internal peripheral faces of slide bearings 27 and 28 are formed as inclined grooves 42A and 42B having prescribed inclinations with a line component C extending in an axial line direction of an external peripheral face of a fixed support shaft 20 as a reference. By this constitution, since the lubrication grooves 42A and 42B are inclined with the line component C extending in the axial line direction of the external peripheral face of the fixed support shaft 20 as a reference, it is avoided that the fixed support shaft 20 crawls into the inclined lubrication grooves 42A and 42B by a simple constitution, and the vibration of the slide bearings 27 and 28 is thereby suppressed.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an electric fluid pump used for an automobile cooling system or the like, and more particularly to an electric fluid pump in which a sliding bearing is fixed to a rotor and an impeller constituting the electric fluid pump.

  In recent years, as the demand for reducing fuel consumption of automobiles has increased, commercialization of automobiles with an idling stop function and hybrid cars has progressed. Since these vehicles also stop the fluid pump driven by the internal combustion engine when the internal combustion engine stops, a drive source for a fluid pump other than the internal combustion engine is required. Moreover, in a hybrid vehicle or an electric vehicle, a travel motor, its control device, or a fluid pump for cooling the battery is required. From these backgrounds, there is a tendency to increase the use of electric fluid pumps that perform a pump action by applying a rotational force to a rotor having an impeller portion fixed using an electric motor.

  For example, in Japanese Unexamined Patent Publication No. 2015-151985 (Patent Document 1), a rotor is accommodated in a space communicating with a pump chamber in which an impeller is accommodated, and liquid-tight from the rotor accommodating space by a partition member made of a nonmagnetic metal. In a canned pump that accommodates a stator including windings in a separated space, the stator is accommodated in a mold in order to insert-mold the stator into a synthetic resin, and when the motor housing is molded with the synthetic resin, An electric fluid pump is described in which a partition member made of a non-magnetic metal is integrally formed of synthetic resin by molding up to the inner peripheral surface with synthetic resin.

  Here, the rotor is formed integrally with the impeller, the rotor is accommodated in the rotor accommodating space, and the impeller is accommodated in the pump chamber. The rotor and the impeller are rotatably supported around the fixed support shaft, and a sliding bearing is fixed to the end portion side of the rotor and the end portion side of the impeller. Therefore, the rotor and the impeller are rotatably supported by the fixed support shaft via the sliding bearing.

Japanese Unexamined Patent Publication No. 2015-151985

  By the way, in the electric fluid pump in which the sliding bearing is fixed to the rotor and the impeller, the configuration of the fixed support shaft and the sliding bearing has a shape as shown in FIG. The overall configuration of the electric fluid pump will be described in detail in an embodiment of the present invention.

  In FIG. 6, reference numeral 50 indicates a fixed support shaft, and a slide bearing fixed to the rotor is rotatably supported around the fixed support shaft 50. Reference numeral 51 is a rotor-side sliding bearing fixed to the end side of the rotor, and reference numeral 52 is an impeller-side sliding bearing fixed to the end side of the impeller. The rotor-side sliding bearing 51 and the impeller-side sliding bearing 52 are integrally molded and fixed at the same time when the rotor and the impeller are molded with synthetic resin.

  A lubricating groove 53A having a triangular cross section is formed on the inner peripheral surface of the rotor side sliding bearing 51, and similarly, a lubricating groove 53B having a triangular cross section is formed on the inner peripheral surface of the impeller side sliding bearing 52. These lubrication grooves 53A and 53B are formed in the axial direction in parallel with the axis of the fixed support shaft 50, and a fluid, for example, cooling water flowing into the rotor accommodating space passes through the lubrication grooves 53A and 53B, and the rotor. Water lubrication is performed by supplying the gap between the inner circumferential surface of the side sliding bearing 51 and the impeller side sliding bearing 52 and the outer circumferential surface of the fixed support shaft 50. In such an electric fluid pump using a sliding bearing, the following problems have been found.

  As shown in FIG. 7, with reference to a line segment extending in the axial direction of a certain outer peripheral position TA of the fixed support shaft 50, the lubricating grooves 53A and 53B at positions as shown in FIG. When the lubricating grooves 53A and 53B are moved to the positions as shown in FIG. 7B by the rotation, the slightly enlarged gap between the lubricating grooves 53A and 53B and the outer peripheral position TA of the fixed support shaft 50. G is formed.

  As a result, a radial mechanical vibration phenomenon occurs between the rotor-side sliding bearing 51, the impeller-side sliding bearing 52, and the fixed support shaft 50. When this vibration phenomenon occurs, a so-called “rattling sound” is generated, which is not preferable as a current fluid pump product. In addition, a new problem arises that this vibration phenomenon increases bearing loss and increases current consumption.

  The reason why such a vibration phenomenon occurs is that the lubricating grooves 53A and 53B formed on the inner peripheral surfaces of the sliding bearings 51 and 52 are formed in parallel with the axis of the fixed support shaft 50. That is, since the lubricating grooves 53A and 53B extend in parallel with the axis of the fixed support shaft 50 with reference to a line segment extending in the axial direction of a certain outer peripheral position TA of the fixed support shaft 50, the outer periphery of the fixed support shaft 50 This is because the surface digs into the inside of the lubricating grooves 53A and 53B and again gets over the lubricating grooves 53A and 53B. As described above, it is required to suppress the rotor-side slide bearing 51 and the impeller-side slide bearing 52 from vibrating in the radial direction between the rotor-side slide bearing 51 and the impeller-side slide bearing 52 and the fixed support shaft 50. ing.

  An object of the present invention is to provide a novel electric fluid pump capable of suppressing the sliding bearing from vibrating in the radial direction with a simple configuration.

  A feature of the present invention is that the lubricating groove formed on the inner peripheral surface of the slide bearing is formed as an inclined groove having a predetermined inclination with reference to a line segment extending in the axial direction of the outer peripheral surface of the fixed support shaft. It is in.

  According to the present invention, since the lubrication groove is inclined with respect to the line segment extending in the axial direction of the outer peripheral surface of the fixed support shaft, the fixed support shaft is suppressed from entering the inclined lubrication groove with a simple configuration. Thus, it is possible to suppress the vibration of the slide bearing.

It is an axial sectional view of the electric fluid pump which becomes an embodiment of the present invention. It is sectional drawing which shows the cross section of the pump part and rotor part which are shown in FIG. It is a block diagram which shows the structure of the slide bearing and fixed support shaft which become embodiment of this invention. It is a block diagram explaining the 1st structure of the lubricating groove provided in the slide bearing. It is a block diagram explaining the 2nd structure of the lubricating groove provided in the slide bearing. It is a block diagram which shows the structure of the conventional sliding bearing and a fixed support shaft. It is explanatory drawing explaining the subject of the conventional slide bearing and a fixed support shaft.

  Embodiments of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to the following embodiments, and various modifications and application examples are included in the technical concept of the present invention. It is included in the range. Embodiments of an electric fluid pump according to the present invention will be described below with reference to the drawings.

  First, the configuration of the electric fluid pump according to the present embodiment will be described. FIG. 1 shows a cross section of the electric fluid pump. The electric fluid pump shown in FIG. 1 is a fluid pump that uses cooling water of a cooling system of an automobile as a working fluid and is incorporated in a circulation circuit connected to a radiator or a thermo core as a heat exchanger. Cooling water is supplied to an engine, a drive motor, an inverter, and the like.

  The electric fluid pump 10 according to the present embodiment includes a pump unit 11, a motor unit 12 as a driving unit that drives the pump unit 11, and a control unit 13 that controls the operation of the motor unit 12. It is configured as a solid.

  The pump unit 11 includes a pump housing 15 that forms a pump chamber 14, and an impeller unit 16 that is rotatably accommodated in the pump chamber 14.

  The pump housing 15 has a suction port (not shown) that opens into the pump chamber 14 and a discharge port (not shown) that opens from the outer periphery of the pump chamber 14 to the outside of the pump chamber 14. The pump unit 11 is a centrifugal pump that applies pressure to the cooling water in the radial direction as the impeller unit 16 rotates. As the impeller unit 16 rotates, the cooling water is sucked into the pump chamber 14 from the suction port, and discharged (pressure-fed) from the discharge port through the discharge channel on the outer peripheral side of the impeller unit 16.

  The impeller portion 16 is an impeller having a plurality of blades 17. The impeller portion 16 is formed integrally with the rotor portion 18 at one end of the rotor portion 18 of the motor portion 12 and is installed in the pump chamber 14. Each blade 17 is arranged radially about the central axis of the rotor portion 18. Each blade 17 is disposed, for example, so as to incline to the opposite side to the rotation direction of the impeller portion 16 toward the outer diameter side, and is installed in a spiral shape as a whole.

  In the pump housing 15, a movement restricting member 19 that restricts movement of the rotor portion 18 and the impeller portion 16 in the axial direction is formed integrally with the pump housing 15. One end of the fixed support shaft 20 of the rotor 18 is inserted in the center of the movement restricting member 19, thereby supporting one end of the fixed support shaft 20.

  The motor unit 12 is a so-called inner rotor type DC brushless motor, and forms a cylindrical stator unit 21, a rotor unit 18 provided on the inner peripheral side of the stator unit 21, and a motor chamber 22 that houses these. It has a housing 23 and a fixed support shaft 20 that is provided in the motor housing 23 and rotatably supports the rotor portion 18.

  The motor housing 23 is made of synthetic resin, and the stator 21 is integrated with the motor housing 23 by insert molding. Similarly, the fixed support shaft 20 is also integrated by insert molding. The motor housing 23 is made of synthetic resin as described above, and has a bottomed cylindrical shape. Then, the fixed support shaft 20 is embedded in the synthetic resin so as to be planted near the center of the circular bottom surface portion 23A.

The stator 21 has a plurality of windings 24, and a magnetic flux is generated on the inner peripheral side by energizing the windings 24. The rotor part 18 has a magnetic pole holding part 25 and a shaft part 26 integrally. For example, the rotor part 18 is formed integrally with the impeller part 16 by injection molding a synthetic resin material. The magnetic pole holding part 25 is composed of a permanent magnet and is firmly attached in the rotor part 18 by a synthetic resin. Since the rotor portion 18 comes into contact with the cooling water, it is important that the magnetic pole holding portion 25 is covered with synthetic resin. The magnetic pole holding portion 25 is connected to the inner peripheral surface of the stator 21 through a slight gap (air gap). It is a columnar member installed so as to be opposed to each other, and a plurality of magnetic poles (permanent magnets in which N poles and S poles are alternately arranged in the circumferential direction) corresponding to the plurality of windings 24 of the stator portion 21 are disposed therein. Is held.

  The shaft portion 26 is a shaft member that transmits power for rotating the impeller portion 16, and is provided coaxially with the magnetic pole holding portion 25 so as to be hollow. A first bearing holding portion and a second bearing holding portion are formed in the vicinity of the magnetic pole holding portion 25 on the end portion side of the rotor portion 18 and in the vicinity of the end portion side of the impeller portion 16, and the first sliding holding portion is formed in these bearing holding portions. A bearing (hereinafter referred to as a rotor-side sliding bearing) 27 and a second sliding bearing (hereinafter referred to as an impeller-side sliding bearing) 28 are respectively installed, and the bearings 27 and 28 are fixed to the rotor 18. Yes.

  Both the rotor-side sliding bearing 27 and the impeller-side sliding bearing 28 are sliding bearings, and the diameter of the inner peripheral surface of each of the sliding bearings 28, 28 is slightly larger than the diameter of the fixed support shaft 20. Lubrication grooves are formed on the inner peripheral surfaces of the slide bearings 28, 28, and water is lubricated by supplying cooling water to the gap between the outer peripheral surfaces of the fixed support shaft 20.

  The fixed support shaft 20 passes through a support hole formed at the shaft center of the rotor 28, and the rotor side sliding bearing 28 fixed to the rotor 18 and the impeller portion 16 are fixed to the rotor 18 in a state where the rotor 18 is installed on the fixed support shaft 20. A slight gap exists between the inner peripheral surface of the fixed impeller slide bearing 28 and the outer peripheral surface of the fixed support shaft 20. That is, the bearings 27 and 28 are slidably provided with respect to the fixed support shaft 20, and the rotor 18 is rotatably supported by the fixed support shaft 20 via the bearings 27 and 28.

  The stator portion 21 has a plurality of salient pole portions 29A formed integrally with an iron core 29 and wound with a winding 24 via a synthetic resin bobbin. The stator portion 21 includes an arc-shaped tooth formed on the salient pole portion 29A. The rotor portion 18 is located around the circumference. Therefore, the rotor portion 18 is rotated by sequentially applying electric power to the winding 24.

  A controller 13 is attached to the opposite surface of the bottom surface 23A of the motor housing 23 on the side where the rotor 18 is located. The control unit 13 is a driver that supplies a drive current for the motor unit 12, and includes a control housing 31 that forms the substrate housing chamber 30, a substrate 32 on which electronic components that are housed in the substrate housing chamber 30 are mounted, and the like. Yes.

  Electronic circuit elements (CPU, transistor, etc.) are mounted on the substrate 32, and a converter and a control circuit are constituted by these circuit elements and capacitors. The converter receives power supply from a battery which is a DC power supply and supplies AC power to the winding 24 of the motor unit 12. The control circuit controls on / off of the MOSFET constituting the converter, and is composed of a microcomputer or the like.

  A partition wall member 33 is disposed between the stator portion 21 and the rotor 18. The partition member 33 is made of a thin metal plate having a thin cross section. The partition member 33 is formed in a straight cylindrical shape having open ends that are open at both ends, and extends along the axial direction of the rotor portion 18. One opening end of the partition member 33 is joined to the side surface portion 23B of the motor housing 23 on the impeller portion 16 side, and the other opening end of the partition member 33 is embedded so as to be embedded in the bottom surface portion 23A of the motor housing 23. .

  As can be seen from FIG. 1, the rotor portion 18 is housed inside the partition member 33, and cooling water is introduced into the partition member 33. Further, the inner peripheral surface of the arc-shaped tooth formed on the salient pole portion 29A of the stator portion 21 is formed in an arc shape that coincides with the outer peripheral surface of the partition wall member 33, and is in metal contact with the outer peripheral surface of the partition wall member 33. ing. As a result, heat from the copper loss of the winding 24 and heat of the internal combustion engine that is input from the surrounding environment are transferred to the partition member 33 via the salient pole portion 29A, and further transferred to the cooling water to be dissipated. It has become.

  FIG. 2 shows the configuration of the impeller portion 16 and the rotor portion 18. In FIG. 2, the rotor part 18 which comprises the motor part 12 is equipped with the magnetic pole which consists of a permanent magnet inside, and is covered with the synthetic resin PR. The synthetic resin PR simultaneously forms the shaft portion 26 and the blade body 40 of the impeller portion 16, and is formed by integrally molding a permanent magnet. As the synthetic resin PR, a PPS (polyphenylene sulfide) resin excellent in heat resistance and dimensional stability is used.

  The blade 17 is formed so as to be planted on the side opposite to the rotor portion 18 side of the blade body 40, and an annular shroud 41 is fixed so as to cover the blade 17. The shroud 41 is also made of PPS resin. An opening 41A for sucking cooling water is formed in the central portion of the shroud 41, and the cooling water sucked from the opening 41A is pressurized by the blades 17 and discharged. Here, since the shape of the shroud 41 and the blade body 40 is complicated, it cannot be molded integrally. Therefore, the shroud 41 and the blade body 40 are formed separately and integrated by ultrasonic welding. ing.

  A rotor-side sliding bearing 27 is attached to the end portion side of the rotor portion 18, and an impeller-side sliding bearing 28 is attached to the end portion side of the impeller portion 16. The rotor side sliding bearing 27 and the impeller side sliding bearing 28 may be integrally molded with the synthetic resin PR, or may be fitted and attached later.

  In the electric fluid pump having such a configuration, as described above, a radial vibration phenomenon occurs between the rotor-side sliding bearing 27, the impeller-side sliding bearing 28, and the fixed support shaft 20. When this vibration phenomenon occurs, it is not preferable as a current fluid pump product.

  The reason why such a vibration phenomenon occurs is that the lubrication grooves formed on the inner peripheral surfaces of the sliding bearings 27 and 28 are formed in parallel with the axis of the fixed support shaft 20 as shown in FIG. Yes. This is because if the lubrication groove extends in parallel with the axis of the fixed support shaft 20, the outer peripheral surface of the fixed support shaft 20 gets into the inside of the lubrication groove and gets over the lubrication groove again.

  In order to deal with such a problem, in the present embodiment, the lubrication groove formed on the inner peripheral surface of the sliding bearing has a predetermined inclination with respect to a line segment extending in the axial direction of the outer peripheral surface of the fixed support shaft 20. The structure formed as the inclined groove | channel which has is proposed. As a result, the lubrication groove is inclined with reference to the line segment extending in the axial direction of the outer peripheral surface of the fixed support shaft 20, so that the fixed support shaft 20 can be prevented from entering the inclined lubrication groove with a simple configuration. As a result, the sliding bearing can be prevented from vibrating.

  Hereinafter, details of the present embodiment will be described with reference to FIGS. FIG. 3 shows the configuration of the fixed support shaft 20, the rotor side sliding bearing 27 and the impeller side sliding bearing 28 according to the present embodiment. Lubricating grooves 42A and 42B formed in the rotor-side sliding bearing 27 and the impeller-side sliding bearing 28 are linear grooves having a cross-section cut into a triangular shape as shown in FIG. 7A. The cross-sectional shape of the lubricating grooves 42A and 42B may be a rectangular shape, a semicircular shape, or the like. The lubricating grooves 42A and 42B connect the inner peripheral surfaces of the rotor side sliding bearing 27 and the impeller side sliding bearing 28 to the upper end surface side openings 43A and 43B and the lower end surface side openings 44A and 44B. The cooling water is supplied to the inner peripheral surfaces of the rotor side sliding bearing 27 and the impeller side sliding bearing 28 through 42B.

  As can be seen from comparison with FIG. 6, in this embodiment, the lubricating grooves 42 </ b> A and 42 </ b> B formed on the inner peripheral surfaces of the rotor-side sliding bearing 27 and the impeller-side sliding bearing 28 are It is characterized in that it is formed to be inclined by an angle θ with reference to a line segment C extending in the direction.

  Thus, since the lubricating grooves 42A and 42B are formed to be inclined with reference to the line segment C extending in the direction of the axis of the outer peripheral surface of the fixed support shaft 20, the lubricating grooves as shown in FIG. Compared to the case where the fixing support shaft 20 extends in the direction, the outer surface in the axial direction of the fixed support shaft 20 is restrained from getting into the inclined lubricating grooves 42A and 42B. As a result, the rotor side sliding bearing 27 and the impeller side sliding bearing 28 can be prevented from vibrating in the radial direction of the fixed support shaft 20.

  Next, the inclination angle of the inclined lubricating grooves 42A and 42B will be described. 4 shows a case where the inclination angle θ is small with reference to the line segment C extending in the axial direction of the outer peripheral surface of the fixed support shaft 20, and FIG. 5 shows a line extending in the axial direction of the outer peripheral surface of the fixed support shaft 20. The case where the inclination angle θ is large with respect to the minute C is shown. In FIGS. 4 and 5, the widths of the lubricating grooves 42A and 42B are set to the same length.

  In FIG. 4, the lubricating grooves 42 </ b> A and 42 </ b> B are inclined with an inclination angle θ <b> 1 with reference to a line segment C extending in the direction of the axis of the outer peripheral surface of the fixed support shaft 20. When this inclination angle θ1 is small, the opening end edges Opu1 and Opu2 of the upper end face side openings 43A and 43B of the lubricating grooves 42A and 42B and the opening end edges Opb1 and Opb2 of the lower end face side openings 44A and 44B of the lubricating grooves 42A and 42B. An overlapping region La is formed between the two.

  That is, the opening edges Opu1 and Opu2 of the lubricating grooves 42A and 42B connected to the upper end surface side openings 43A and 43B of the impeller side sliding bearing 28 and the rotor side sliding bearing 27 and the opening end edge Opb1 connected to the lower end surface side openings 44A and 44B. , Opb2 are projected on each other, an overlapping region La is formed.

  Therefore, since this overlapping region La is parallel to the axis of the fixed support shaft 20, vibration in the radial direction is generated in the same manner as the structure shown in FIG. However, since the width of the overlapping region La is smaller than the width of the lubricating grooves 42A and 42B, the amplitude of the vibration is slight as compared with FIG. For this reason, it is possible to suppress the fixed support shaft 20 from entering into the inclined lubricating grooves 42A and 42B, thereby suppressing the vibration of the sliding bearing.

  On the other hand, FIG. 5 shows an example in which the inclination angles of the lubricating grooves 42A and 42B are increased. In FIG. 5, the lubricating grooves 42 </ b> A and 42 </ b> B are inclined with an inclination angle θ <b> 2 with reference to a line segment C extending in the direction of the axis of the outer peripheral surface of the fixed support shaft 20. When the inclination angle θ2 is large, the opening end edges Opu1 and Opu2 of the upper end face side openings 43A and 43B of the lubricating grooves 42A and 42B, and the opening end edges Opb1 and Opb2 of the lower end face side openings 44A and 44B of the lubricating grooves 42A and 42B. During this period, the overlapping region La is not formed.

  That is, the opening edges Opu1 and Opu2 of the lubricating grooves 42A and 42B connected to the upper end surface side openings 43A and 43B of the impeller side sliding bearing 28 and the rotor side sliding bearing 27 and the opening end edge Opb1 connected to the lower end surface side openings 44A and 44B. , Opb2 are projected on each other, the overlapping region La is not formed.

  Therefore, since there is no overlapping region La, the fixed support shaft 20 is not parallel to the axis line, and the fixed support shaft 20 is prevented from entering into the inclined lubricating grooves 42A and 42B, thereby causing the sliding bearing to vibrate. It becomes possible to suppress this.

  According to this embodiment, since the lubricating groove is inclined with reference to a line segment extending in the direction of the axis of the outer peripheral surface of the fixed support shaft, the fixed support shaft can be inserted into the inclined lubricating groove with a simple configuration. This suppresses the vibration of the sliding bearing.

  Next, the inclination direction of the lubricating grooves 42A and 42B will be described. Returning to FIG. 3, the rotor 18 part is rotated to the right, and of course, the rotor side sliding bearing 27 and the impeller side sliding bearing 28 are also rotated to the right, and the arrow AW indicates the direction of rotation in FIG. 3. ing.

  Here, the pressure of the cooling water is higher on the rotor side than on the pump side. For this reason, the flow of the cooling water near the rotor side sliding bearing 27 and the impeller side sliding bearing 28 flows from the rotor side to the impeller side. Therefore, in the present embodiment, the lubricating grooves 42A and 42B are arranged in such a direction that the upper end side openings 43A and 43B are on the rear side with respect to the lower end side openings 44A and 44B of the rotor side slide bearing 27 and the impeller side slide bearing 28. It is formed to be inclined.

  That is, when the rotor-side sliding bearing 27 and the impeller-side sliding bearing 28 rotate with respect to a certain line segment C in the axial direction of the outer peripheral surface of the fixed support shaft 20, first, the openings of the lower end surface side openings 44A and 44B are opened. The end edges Opb1 and Opb2 pass through the line segment C, and then the opening end edges Opu1 and Opu2 of the upper end surface side openings 43A and 43B pass through the line segment C. Therefore, the cooling water in the lubricating grooves 42A and 42B flowing from the rotor side to the impeller side can smoothly flow out to the upper end surface side openings 43A and 43B side.

  For example, if the inclination is in the opposite direction, the cooling water flowing in the lubrication grooves 42A and 42B flowing from the rotor side to the impeller side flows out in the rotation direction, so that the upper end surface side openings 43A and 43B side. It becomes difficult to flow out smoothly. For this reason, in this embodiment, it is set as the inclination direction as shown in FIG.

  As described above, according to the present invention, the lubricating groove formed on the inner peripheral surface of the slide bearing has an inclination having a predetermined inclination with reference to a line segment extending in the direction of the axis of the outer peripheral surface of the fixed support shaft. The structure is formed as a groove. According to this, since the lubrication groove is inclined with reference to a line segment extending in the direction of the axis of the outer peripheral surface of the fixed support shaft, it is possible to prevent the fixed support shaft from entering the inclined lubrication groove with a simple configuration. As a result, the sliding bearing can be prevented from vibrating.

  In addition, this invention is not limited to an above-described Example, Various modifications are included. For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Further, it is possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.

  DESCRIPTION OF SYMBOLS 10 ... Electric fluid pump, 11 ... Pump part, 12 ... Motor part, 13 ... Control part, 14 ... Pump chamber, 15 ... Pump housing, 16 ... Impeller part, 17 ... Blade | wing, 17A ... Welding surface, 18 ... Rotor part, DESCRIPTION OF SYMBOLS 19 ... Movement control member, 20 ... Support shaft, 21 ... Stator part, 22 ... Motor chamber, 23 ... Motor housing, 24 ... Winding, 25 ... Magnetic pole holding part, 26 ... Shaft part, 27, 28 ... Bearing, 29 ... Iron core, 29A ... salient pole part, 34 ... discharge passage, 40 ... blade part body, 41 ... shroud, 42A, 42B ... lubrication groove, 43A, 43B ... upper end side opening, 44A, 44B ... lower end side opening.

Claims (3)

A pump unit composed of an impeller,
A rotor unit integrally coupled with the impeller;
A motor part composed of the rotor part and the stator part;
A control unit that drives and controls the motor unit;
The impeller side sliding bearing fixed to the end portion side of the impeller, and the fixed support shaft that pivotally supports the rotor side sliding bearing fixed to the end portion side of the rotor portion,
The lubrication grooves formed on the inner peripheral surfaces of the impeller side slide bearing and the rotor side slide bearing have an inclination having a predetermined inclination angle with reference to a line segment extending in the direction of the axis of the outer peripheral surface of the fixed support shaft. An electric fluid pump characterized by being formed as a groove. The electric fluid pump according to claim 1,
The inclination angle of the lubrication groove is obtained by projecting the opening edge of the lubrication groove connected to the upper end surface side opening of the impeller side sliding bearing and the rotor side sliding bearing and the opening edge connected to the lower end surface side opening of each other. An electric fluid pump characterized in that the angle is determined so that the overlapping region is not formed. The electric fluid pump according to claim 2,
When the rotor side sliding bearing and the impeller side sliding bearing rotate with respect to the line segment in the axial direction of the outer peripheral surface of the fixed support shaft, the inclined groove first opens the opening of the lower end surface side opening. An electric fluid pump, wherein an end edge passes through the line segment, and thereafter, the opening edge of the upper end surface side opening is inclined in a direction passing through the line segment.

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