JP5714921B2 - Liquid pump - Google Patents

Description

  The present invention relates to a technical field of a liquid pump used when circulating a coolant through a cooling device mounted on a vehicle.

  In general, in an electric vehicle or a hybrid vehicle, an electric liquid pump is frequently used as a constituent member of cooling means for cooling a drive motor or a motor control unit. In such a liquid pump, a stator unit in which a coil is wound around a stator core formed by laminating a plurality of core materials, and a plurality of pairs of magnetic poles in a circumferential direction at a base end portion of an impeller portion including a blade body. A rotor unit integrally formed with a cylindrical magnetic pole portion, a partition wall having a bottomed cylindrical portion, a stator housing portion that houses the stator unit, and a rotor housing portion that houses the rotor unit However, there is a configuration in which a housing formed by partitioning inside and outside the bottomed cylindrical portion and a cover body that covers the rotor housing portion and forms a pump chamber are provided. And in this, the rotor unit is configured such that the boss cylinder part formed in the shaft core part is rotatably fitted and supported on the rotor shaft supported by the bottom piece part whose base end part constitutes the partition wall. It is the structure which rotates in a rotor accommodating part.

JP 2001-304165 A

  However, in the above-mentioned conventional one, the rotor unit has a long cylindrical magnetic pole portion integrally formed on the base end side of the impeller portion, and the magnetic pole portion on the base end side is fitted outside the bottomed cylindrical portion of the partition wall. The boss cylinder part formed in the shaft core part of the impeller part on the front end side is rotatably supported by being externally fitted to the rotor shaft protruding toward the front end side from the bottom piece part of the bottomed cylindrical part. It has a configuration. For this reason, the rotor unit is configured to be supported in an unbalanced and unstable state in which the tip side portion is supported by the rotor shaft with respect to the entire length in the axial direction. In such a configuration, when the rotor unit rotates, if there is a dimensional error in the rotor unit and the rotor shaft or a slight external force acting on the rotor unit is applied, the boss cylinder is The rotor unit may swing greatly. In this case, there is a problem that not only abnormal noise is generated and pump performance is lowered, but also the boss cylinder is worn by rubbing against the rotor shaft and durability is impaired. In addition, in this case, since the rotor shaft is cantilevered so that only the base end portion is supported, it is conceivable that the rotor shaft is inclined and the swinging of the rotor unit becomes more prominent. There is a problem that an increase in sound, a further decrease in pump performance and durability is assumed, and this is a problem to be solved by the present invention.

The present invention was created in view of the above-described circumstances in order to solve these problems. The invention of claim 1 is directed to winding a coil around a stator core formed by laminating a plurality of core materials. A rotor unit in which a cylindrical magnetic pole portion composed of a plurality of pairs of magnetic poles in the circumferential direction is integrally formed at a base end portion of an impeller portion including a blade body, and a mounted stator unit;
Comprising a partition wall having a bottomed cylindrical portion, and the housing and the rotor accommodating portion for accommodating a stator accommodating portion said rotor unit for accommodating the stator unit is a partition formed on the inside and outside of the bottomed cylindrical portion, the rotor base in the liquid pump comprising using a cover body accommodating portion and covering forming the pumping chamber, the boss cylindrical portion provided in the axial center portion of the impeller of the rotor unit, the bottom piece portion constituting the partition wall part Upon is allowed to rotatably fitted supported on the rotor shaft supported, the boss cylindrical portion formed so as to extend into the cylindrical space of the magnetic pole portion, the bottom piece portion of the septum proximal to the axial core portion A concave concave-shaped portion is formed toward the side, and the base end portion of the boss cylinder portion is formed so as to face the distal end portion of the stator unit in the radial direction, and the magnetic pole portion of the rotor unit Is Serial and wherein the outer diameter side portion of the impeller than the coil proximal end of the stator units are formed by allowed projecting proximally so as to face the stator unit in the radial direction, the center of gravity of the rotor unit of the boss cylindrical portion The liquid pump is characterized in that the setting is located on the distal end side with respect to the proximal end.
In the second aspect of the present invention, the distal end portion of the rotor shaft projecting from the distal end of the boss cylinder unit claims, characterized by being configured to be supported on the rotor shaft support portion integrally formed on the cover body 1. The liquid pump according to 1.
4. The rib according to claim 3, wherein a suction port for sucking liquid is disposed above the cylinder portion of the cover body and protrudes downward from the circumferential direction into the cylinder at the lower end portion of the suction port. The liquid pump according to claim 2, wherein the rotor shaft support portion supports the rotor shaft in a state of being supported by the rib .

According to the first aspect of the invention, when the rotor unit rotates, the rotor unit is not out of balance and swung with a slight load, and the durability of the liquid pump is improved.
According to the invention of claim 2, it is possible to provide a liquid pump having a predetermined motor performance without being increased in size while being a liquid pump excellent in durability.
According to the third aspect of the present invention, the rotor shaft is supported in a doubly supported manner, and the swinging of the rotor unit is further prevented, and the durability is further improved.

1A and 1B are a front view and a plan view of a liquid pump, respectively. It is front sectional drawing of a liquid pump.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Reference numeral 1 denotes a liquid pump used to circulate cooling water (liquid) through a cooling device such as a radiator. The liquid pump 1 has a proximal half (the lower half in FIGS. 1A and 2). Is housed in the housing 2. 2, the housing 2 is formed concentrically with the small-diameter cylindrical portion 2a (corresponding to the cylindrical portion of the present invention) and the small-diameter cylindrical portion 2a, and is on the outer diameter side of the small-diameter cylindrical portion 2a. And a large-diameter cylindrical portion 2b that covers the surface. And the small diameter cylinder part 2a forms the bottomed cylindrical space which the bottom opens with the bottom piece part 2c integrally formed in the front-end | tip part (upper end part) of this small diameter cylinder part 2a, and this space is a stator. It is comprised in the accommodating part SH. On the other hand, the large-diameter cylindrical portion 2b is connected together with a small-diameter cylindrical portion 2a and a ring-shaped coupling piece portion 2d that is integrally formed so as to connect lower end edges of the small-diameter cylindrical portion 2a and the large-diameter cylindrical portion 2b. A bottomed ring cylindrical space is formed with the piece portion 2d as a bottom piece and opened upward, and the space is configured in the rotor accommodating portion RH. The portion of the housing 2 from the connecting piece portion 2d to the small diameter cylindrical portion 2a and the bottom piece portion 2c corresponds to the partition wall D of the present invention, and the bottomed cylindrical portions (small diameter cylindrical portion 2a, bottom piece portion 2c) The provided partition wall D is configured to partition (separate) the stator housing portion SH formed on the inner diameter side and the rotor housing portion RH formed on the outer diameter side in a state of facing each other in the radial direction.

Further, the housing 2 is integrally formed with a base piece portion 2e extending in the outer diameter direction from the outer peripheral surface of the lower end portion of the large-diameter cylindrical portion 2b, and fixed pieces 2f are provided at three locations around the outer periphery of the base piece portion 2e. The liquid pump 1 is fixed in the vicinity of the cooling device through the fixed pieces 2f, and the fixed piece 2f is configured to be provided with a vibration isolating member 2g. The base piece portion 2e of the housing 2 is formed with a support piece portion 2h that protrudes downward, and the base piece portion 2e is a space that opens downward together with the support piece portion 2h. The housing part CH is configured. Further, a flange piece 2i extending to the outer diameter side is integrally formed at the upper end portion of the large diameter cylindrical portion 2b.
On the other hand, the bottom piece 2c of the housing 2 is recessed toward the inner diameter side downward (on the inner side of the small-diameter cylindrical portion 2a and on the stator accommodating portion SH side), and is recessed facing the stator accommodating portion SH in the radial direction. The columnar portion 2j is formed, and the column portion 2k that protrudes downward from the groove bottom of the recessed portion 2j is integrally formed. The column portion 2k has a base edge located on the distal end side of the connecting piece portion 2d, and is formed concentrically with the small-diameter cylindrical portion 2a and the large-diameter cylindrical portion 2b, and the bottom piece portion 2c and the small-diameter cylindrical portion 2a. It is comprised so that it may become an axial center part of stator accommodating part SH comprised by these.

  Then, the stator unit 3 that is a constituent member of the brushless motor is housed in the stator housing portion SH (inside the small-diameter cylindrical portion 2a) on the inner diameter side that is the base end side (lower part) of the partition wall D of the housing 2. The stator unit 3 includes a stator core 3b configured by laminating a plurality of core materials 3a formed in a ring-shaped disk shape with an iron plate material in the vertical direction. The stator core 3b is formed with a plurality of teeth (not shown) that are long in the vertical direction in the circumferential direction by forming a plurality of teeth adjacent to the outer circumference in the circumferential direction. A stator unit 3 having a plurality of coils 3d formed in a circumferential direction is formed on the outer periphery by attaching an insulator 3c to a plurality of teeth on the outer periphery of the stator core 3b and winding the winding. ing. The stator unit 3 is fixed to the stator housing portion SH by fitting a through hole 3e formed in the shaft core portion of the stator core 3b to the support column portion 2k of the housing 2, and in this fixed state, the stator unit 3 The distal end of the concave portion 2j is disposed so as to face the radial direction in the groove of the recessed portion 2j, while the inner peripheral surface of the small diameter cylindrical portion 2a and the outer peripheral surface of the stator unit 3 are disposed close to each other. ing.

On the other hand, the base end portion 4a (lower end portion) of the rotor shaft 4 is fixed in a state where it is embedded in a support column portion 2k which is an axial center portion of the bottom piece portion 2c of the housing 2. Thereby, the rotor shaft 4 protrudes upward from the bottom of the recessed portion 2j of the bottom piece 2c and is exposed in the rotor accommodating portion RH, but the base end side (lower side) of the exposed portion is recessed. Located in the groove of the portion 2j, the distal end side (upper side) is disposed so as to protrude further toward the distal end side than the bottom piece portion 2c constituting the partition wall D.
In the present embodiment, the housing 2 is formed by molding a resin material, and the stator unit 3 and the rotor shaft 4 are insert-molded in the housing 2 in advance.

A rotor unit 5 is a constituent member of the brushless motor, and the rotor unit 5 is rotatably fitted and supported on a portion protruding upward from the bottom piece 2c of the rotor shaft 4, whereby the rotor unit 5 is supported. Is configured to rotate in the rotor accommodating portion RH of the housing 2.
The rotor unit 5 includes an impeller portion 6 on the distal end side (upper end side) and a magnetic pole portion 7 on the proximal end side (lower end side). The impeller portion 6 is formed of a resin material, and includes a disk-shaped base piece 6a that bulges upward and a plurality of circumferentially extending blade bodies 6b that protrude upward from the upper surface of the base piece 6a. Has been. Further, a boss cylinder portion 6c is formed on the shaft core portion of the base piece 6a.
On the other hand, the magnetic pole portion 7 is formed in a cylindrical shape by a resin material (for example, ferrite bond) containing magnetic powder, and the rotor unit 5 is formed by integrating the upper end portion with the outer peripheral portion of the base piece 6a of the impeller portion 6. Is formed. The magnetic pole portion 7 is configured to be integrated with the impeller portion 6 to form a plurality of pairs of magnetic poles in the circumferential direction by magnetizing the rotor unit 5 after molding.

Here, the magnetic pole portion 7 of the rotor unit 5, as is apparent from FIG. 2, longer protrudes from the outer diameter side portion toward the base end side of the impeller 6 so as to face the stator unit 3 in the radial direction, the coil It is formed so as to protrude from the base end to the base end side . For this reason, the position of the center of gravity M in the axial direction of the rotor unit 5 is set so as to be located on the magnetic pole part 7 side, which is the base end side of the impeller part 6. In the rotor unit 5 in which the present invention is implemented, the boss cylinder portion 6c formed on the shaft core portion of the impeller portion 6 is formed to extend long in the cylinder of the magnetic pole portion 7, and the boss cylinder portion 6c In other words, the position of the center of gravity M of the rotor unit 5 is located closer to the front end side than the base end of the boss cylinder portion 6c so that the base end edge is positioned on the base end side beyond the position of the center of gravity M of the rotor unit 5. that it has been set so.

The rotor unit 5 is supported by the housing 2 at its lower end, and is rotatably mounted on the rotor shaft 4 by fitting the boss cylinder portion 6c of the impeller portion 6 to the rotor shaft 4 protruding above the partition wall D. In this state, the center of gravity M of the rotor unit 5 is positioned at the outer fitting portion of the rotor shaft 4 so that the rotor unit 5 is supported by the rotor shaft 4 in a stable state. At this time, the boss cylinder part 6c is formed to have an outer diameter that can be fitted in the recessed part 2j constituting the partition wall D, whereby the rotor unit 5 can be connected to the boss cylinder part 6c (rotor unit). When the base end portion of 5) is fitted in the groove of the recessed portion 2j so as to be close to and opposed to the groove bottom of the recessed portion 2j, the base end side portion of the boss tubular portion 6c is the stator unit. It is comprised so that it may become the positional relationship which opposes the front-end | tip side site | part of 3 to radial direction. Thus, the length in the vertical direction of the stator unit 3 can be shortened while the length in the axial direction of the boss cylinder portion 6c is extended to the base end side beyond the position of the center of gravity M of the rotor unit 5. In consideration, the liquid pump 1 having a predetermined motor performance can be formed without increasing the size.
On the other hand, the rotor shaft 4 penetrates the boss cylinder part 6c, and the front-end | tip part 4b used as this penetration end part is comprised so that it may protrude from the boss | hub cylinder part 6c front-end | tip.

  Reference numeral 8 denotes a cover body that accommodates the front half (upper half) of the liquid pump 1, and the cover body 8 is configured to cover the rotor housing RH that is the front side (upper part) of the partition wall D. Has been. The cover body 8 is formed of a resin material, and includes a cylindrical portion 8a having substantially the same diameter as the large-diameter cylindrical portion 2b of the housing 2 and an inclined bottom piece 8b that is inclined so as to protrude upward. Is formed in a bottomed cylindrical shape with an opening. The cylindrical portion 8a is integrally formed with an attachment piece portion 8c extending from the opening edge, which is the lower end edge, to the outer diameter side and fixed to the flange portion 2i of the housing 2, and extending horizontally from the outer peripheral surface. A narrow cylindrical discharge port 8d that protrudes and communicates with the cylindrical portion 8a is formed. On the other hand, a thin cylindrical suction port 8e that protrudes upward and communicates with the cylindrical portion 8a is integrally formed at the axial core portion of the inclined bottom piece 8b. Further, a plurality of ribs 8f (three in the present embodiment) protruding downward from three places in the circumferential direction are integrally formed in the cylinder at the lower end of the suction port 8e and supported by these ribs 8f. In this state, the rotor shaft support portion 8g is integrally formed, and the rotor shaft support portion 8g is formed with a concave groove portion 8h that opens downward and is concentric with the small diameter cylindrical portion 2a and the large diameter cylindrical portion 2b. Yes.

And the cover body 8 is a front-end | tip part which protrudes from the boss | hub cylinder part 6c of the said rotor shaft 4 with respect to the housing 2 in which the stator 3, the rotor shaft 4, and the rotor unit 5 were integrated in the recessed groove part 8h of the rotor shaft support part 8b. On the other hand, the mounting piece 8c formed at the lower end of the cylindrical portion 8a is abutted against the flange piece 2i formed at the upper end of the large-diameter cylindrical portion 2b (housing 2). It is configured to be fixed to the housing 2 in a sealed manner. In this fixed state, the cover body 8 is configured to cover the rotor housing portion RH and configure the rotor housing portion RH in the pump chamber PR, and to support the tip portion 4b of the rotor shaft 4. Thus, the rotor shaft 4 is configured such that the base end portion 4a is supported by the partition wall D and the tip end portion 4b is supported by the cover body 8 so as to receive a double-sided support.
Reference numeral 9 denotes a washer interposed between the rotor shaft support portion 8g of the cover body 8 and the boss cylinder portion 6c of the impeller portion 6. Reference numeral 10 denotes a groove bottom of the recessed portion 2j constituting the partition wall D and the impeller portion 6. The rotor unit 5 includes a blade body 6b and a cover body 8 in a state where an upper end surface of the boss cylinder portion 6c of the impeller portion 6 is in contact with the washer 9. A predetermined gap is set between the inclined bottom piece 8b.

The liquid pump 1 configured as described above is configured such that external power is supplied to the stator unit 3 via the control circuit of the control board 11 provided in the control device housing portion CH of the housing 2. When the coil 3d is excited in accordance with the power supply to the unit 3, the magnetic pole portion 7 that is close to and opposed to the stator unit 3 in the radial direction rotates together with the impeller portion 6, whereby the liquid is supplied to the cover body 8. It is configured to perform a pump operation for sucking from the formed suction port 8e and discharging from the discharge port 8d.
At this time, the center of gravity M of the rotor unit 5 is located on the distal end side of the base end of the boss cylinder portion 6c. Therefore, the center of gravity M is located on the outer fitting portion of the rotor unit 5 to the rotor shaft 4. Is configured to do. As a result, when the rotor unit 5 is supported by the rotor shaft 4 in a balanced and stable state and is rotated about the rotor shaft 4 as an axis, not only can the rotational operation be performed in a stable state, but also the rotor Even if an external force acts on the unit 5, the balance of the rotor unit 5 is not lost and stable rotation can be maintained, and the rotor unit 5 swings and wears the rotor shaft 4. This is configured so that durability can be improved.

  In the present embodiment configured as described, the liquid pump 1 includes an impeller portion 6 including a stator unit 3 in which a coil 3d is wound around a stator core 3b formed by laminating a plurality of core materials 3a, and a blade body 6b. A bottomed cylindrical portion formed by a rotor unit 5 in which a cylindrical magnetic pole portion 7 composed of a plurality of pairs of magnetic poles in the circumferential direction is integrally formed, and a small diameter cylindrical portion 2a and a bottom piece portion 2c. And a rotor housing portion in which a stator housing portion SH for housing the stator unit 3 and a rotor housing portion RH for housing the rotor unit 5 are partitioned and formed inside and outside the bottomed cylindrical portion. The cover body 8 that covers the RH to form the pump chamber PR is used, but the boss cylinder portion 6c provided on the shaft core portion of the impeller portion 6 of the rotor unit 5 is a bottom piece constituting the partition wall D. In part 2c In order to rotatably fit and support the rotor shaft 4 with the end portion supported, the boss cylinder portion 6c is formed to extend so as to protrude into the cylinder of the magnetic pole portion 7, and the position of the center of gravity M of the rotor unit 5 is the boss. It is comprised so that it may be located in the front end side rather than the base end of the cylinder part 6c. As a result, when the rotor unit 5 is externally fitted to the rotor shaft 4, the center of gravity M of the rotor unit 5 is positioned at the external fitting portion to the rotor shaft 4, and the rotor unit 4 is in a stable and well-balanced state. Is supported by external fitting. As a result, when the rotor unit 5 rotates about the rotor shaft 4 as an axis, even if a load acts on the magnetic pole portion 7, a stable rotational state can be maintained without losing the balance. There is no problem that the rotor shaft 4 is worn out by swinging, the durability is improved, and the highly reliable liquid pump 1 can be provided.

  As described above, in the embodiment in which the present invention is implemented, the rotor unit 5 is stable in a state where the center of gravity M of the rotor unit 5 is located at the outer fitting portion of the rotor shaft 4 ロ ー タ. However, in this case, the portion of the bottom piece 2c of the partition wall D that supports the rotor shaft 4 is a concave concave portion 2j toward the base end, and the center of gravity M When the boss cylinder portion 6c formed so as to extend in the axial direction so as to reach the base end side from the position is externally fitted to the rotor shaft 4, the base end portion of the boss cylinder portion 6c is radially directed to the distal end portion of the stator unit 3. It is comprised so that it may oppose. As a result, the boss cylinder portion 6c that is long in the axial direction is configured to be externally fitted to the rotor shaft 4 protruding toward the distal end side of the partition wall D, and the durability is improved. It is not necessary to shorten the length of the stator unit 3 disposed in the vertical direction, and it is possible to make the liquid pump 1 having a predetermined motor performance excellent in durability without increasing the size.

  Further, in this configuration, the tip end portion 4b of the rotor shaft 4 protruding from the tip end of the boss cylinder portion 6c is supported by the rotor shaft support portion 8g formed integrally with the cover body 8. Since it is supported in a held state, rattling is prevented, and the rotor unit 5 can be prevented from swinging further, and the durability can be further improved.

  The present invention provides a liquid having a housing in which a stator housing portion for housing a stator unit and a rotor housing portion for housing a rotor unit are partitioned and formed inside and outside the bottomed tubular portion by a partition wall having a bottomed tubular portion. Can be used for pumps.

DESCRIPTION OF SYMBOLS 1 Liquid pump 2 Housing 2a Small diameter cylinder part 2b Large diameter cylinder part 3 Stator 3b Stator core 4 Rotor shaft 5 Rotor unit 6 Impeller part 6a Base piece 6b Blade body 6c Boss cylinder part 7 Magnetic pole part 8 Cover body 8d Discharge port 8
8e Suction port 8g Rotor shaft support M Center of gravity

Claims (3)

A stator unit in which a coil is wound around a stator core formed by laminating a plurality of core materials;
A rotor unit in which a cylindrical magnetic pole portion composed of a plurality of pairs of magnetic poles in the circumferential direction is integrally formed at a base end portion of an impeller portion including a blade body;
Comprising a partition wall having a bottomed cylindrical portion;
A housing and a rotor accommodating portion for accommodating the stator housing portion and said rotor unit for accommodating the stator unit is a partition formed on the inside and outside of the bottomed cylindrical portion,
In a liquid pump using a cover body that covers the rotor housing portion and forms a pump chamber,
A boss cylindrical portion provided in the axial center portion of the impeller of the rotor unit, when allowed to rotatably fitted supported on the rotor shaft having a base end portion is supported by the bottom piece portion constituting the partition wall,
The boss cylindrical portion formed so as to extend into the cylindrical space of the magnetic pole portions,
The bottom piece portion of the partition wall is formed with a concave concave portion toward the proximal end side in the shaft core portion,
The base end portion of the boss cylinder portion is formed so as to face the distal end portion of the stator unit in the radial direction,
The magnetic pole part of the rotor unit is formed so as to protrude from the outer diameter side part of the impeller part to the base end side rather than the coil base end of the stator unit so as to face the stator unit in the radial direction.
The liquid pump according to claim 1, wherein the center of gravity of the rotor unit is set to be positioned on the distal end side of the base end of the boss cylinder portion. The tip portion of the rotor shaft projecting from the distal end of the boss cylindrical portion, the liquid pump according to claim 1, characterized by being configured to be supported on the rotor shaft support portion integrally formed on said cover member. In the cover body, a suction port for sucking liquid is disposed above the cylinder portion of the cover body,
A rib projecting downward from the circumferential direction is formed in the cylinder at the lower end of the suction port,
The liquid pump according to claim 2, wherein the rotor shaft support portion supports the rotor shaft in a state of being supported by the rib.

Images