At least an embodiment of the present invention relates to a pump device and a motor used for the pump device.
Patent Literature 1 discloses a pump device configured to rotate an impeller by a motor. The motor used for the pump device of Patent Literature 1 includes a rotor and a stator arranged on an outer peripheral side of the rotor, and the stator is covered with a resin sealing member and sealed. The stator includes a stator core, an insulator, and a coil wire wound around the insulator.
Patent Literature 2 discloses a motor configured such that conductive wires forming coils are in star connection to form a common wire. In the motor of Patent Literature 2, when a circuit board is fixed to an insulator, the common wire is housed between the insulator and the circuit board. Alternatively, when a cap member is attached to cover the circuit board, the common wire is housed between the cap member and the circuit board or the insulator. This ensures insulation of the common wire.
In the motor described in Patent Literature 2, another member such as the circuit board or the cap needs to be assembled to the insulator to hold the common wire and ensure insulation. On the other hand, when the structure in which the stator is covered with the resin sealing member as in Patent Literature 1 is employed, the resin sealing member can ensure insulation of the common wire. However, Patent Literature 1 does not describe the method of holding the common wire such that the common wire does not protrude from the resin sealing member when the resin sealing member is formed. In particular, the method of holding the common wire such that the common wire does not protrude to an outer peripheral side of the stator without using another member such as the circuit board at a stage before the stator is integrally formed with the resin sealing member is not described.
Typically, the method of pushing the common wire into a gap between coils adjacent to each other in the circumferential direction is also used as the method of holding the common wire, but a gap needs to be provided between the coils. Further, there is also the method of fixing the common wire to the stator with an adhesive. However, adhesive curing time is needed, and for this reason, productivity is low.
In view of the above-described problems, at least an embodiment of the present invention holds a common wire such that the common wire does not protrude to an outer peripheral side of a stator.
For solving the above-described problems, the motor of at least an embodiment of the present invention includes a rotor and a stator arranged on an outer peripheral side of the rotor. The stator includes a stator core, a plurality of insulators covering the stator core, a coil wound around the stator core through each of the insulators, and a common wire formed of a conductive wire drawn from the coil. At least one of the plurality of insulators includes a first common wire support portion configured to support the common wire from the outside in a radial direction. The first common wire support portion is in a shape extending inward in the radial direction toward a tip end side of the common wire.
In the motor of at least an embodiment of the present invention, the insulator is provided with the first common wire support portion configured to support the common wire from the outside in the radial direction. The first common wire support portion is in the shape extending inward in the radial direction toward the tip end side of the common wire, and therefore, protrusion of the common wire to the outer peripheral side of the first common wire support portion can be suppressed. Thus, exposure of the common wire to the outer peripheral side of the stator can be suppressed.
As described above, the motor of at least an embodiment of the present invention is configured so that the common wire can be temporarily fixed to the insulator with the common wire being supported by the first common wire support portion. Thus, for example, in the case of sealing the stator with the resin sealing member, the common wire can be held so as not to protrude to the outside of the resin sealing member. Thus, the common wire can be insulated. Further, the first common wire support portion is integrally formed with the insulator, and therefore, another component for suppressing protrusion of the common wire is not necessarily used. Thus, an increase in the number of components can be suppressed.
In at least an embodiment of the present invention, the insulator provided with the first common wire support portion preferably includes a second common wire support portion connected to an end portion of the first common wire support portion, the end portion being on an inner side in the radial direction. With this configuration, a tip end portion of the common wire can be supported by the second common wire support portion. Thus, exposure of the common wire to the outer peripheral side of the stator can be suppressed.
At least an embodiment of the present invention preferably includes a resin sealing member configured to cover the stator. The resin sealing member is preferably provided with a plurality of holes as arrangement marks of pressing members configured to press the stator against a mold for forming the resin sealing member. The second common wire support portion is preferably arranged in an angular range including an angular position of any of the plurality of holes. With this configuration, the common wire can be supported so as not to protrude to the pressing member side, and contact between each of the pressing members and the common wire can be prevented. Thus, disconnection of the common wire due to the common wire being caught between the pressing member and the insulator can be prevented.
In at least an embodiment of the present invention, one of the plurality of insulators is preferably connected to a connector, the insulator adjacent, in a circumferential direction, to the insulator connected to the connector preferably includes a conductive wire guide portion configured to guide a conductive wire drawn from the coil to the connector, and the conductive wire guide portion is preferably arranged in an angular range including an angular position of any of the plurality of holes. With this configuration, the conductive wire can be supported so as not to protrude to the pressing member side, and contact between each of the pressing members and the conductive wire can be prevented. Thus, disconnection of the conductive wire due to the conductive wire being caught between the pressing member and the insulator can be prevented.
In at least an embodiment of the present invention, at least one of the insulators adjacent, in the circumferential direction, to the insulator provided with the first common wire support portion preferably includes a common wire guide portion configured to guide the common wire. With this configuration, the common wire can be easily drawn toward the first common wire support portion.
In at least an embodiment of the present invention, the first common wire support portion is preferably provided at a single location on each end side of the insulator in the circumferential direction. This configuration can be applied regardless of whether the direction of drawing the common wire is a first side or a second side in the circumferential direction.
In at least an embodiment of the present invention, each of the insulators preferably includes a jumper wire guide portion configured to guide a jumper wire connecting the coils of an identical phase. With this configuration, the jumper wire can be drawn in an appropriate path.
In this case, each of the insulators is preferably provided with the jumper wire guide portion at two locations spaced apart in the circumferential direction, and each jumper wire preferably includes a pushed portion pushed into a gap between the jumper wire guide portions at the two locations. With this configuration, looseness of the jumper wire can be suppressed, whereby expansion of the jumper wire to the outer peripheral side can be suppressed.
Next, a pump device of at least an embodiment of the present invention includes the above-described motor, an impeller attached to a rotating shaft of the rotor, and a pump chamber in which the impeller is arranged.
According to at least an embodiment of the present invention, the insulator is provided with the first common wire support portion configured to support the common wire from the outside in the radial direction. The first common wire support portion is in the shape extending inward in the radial direction toward the tip end side of the common wire, and therefore, protrusion of the common wire to the outer peripheral side of the first common wire support portion can be suppressed. Thus, exposure of the common wire to the outer peripheral side of the stator can be suppressed.
Embodiments will now be described, by way of example only, with reference to the accompanying drawings which are meant to be exemplary, not limiting, and wherein like elements are numbered alike in several Figures, in which:
Hereinafter, an embodiment of a pump device and a motor to which at least an embodiment of the present invention is applied will be described with reference to the drawings.
In the present Description, a reference symbol L indicates an axial direction of the motor 2, an output side L1 is a first side in the direction of an axis L, and an opposite-output side L2 is a second side in the direction of the axis L.
The case body 3 is placed on the cover member 14 from the output side L1. Thus, a space partitioned between the cover member 14 and the case body 3 serves as the pump chamber 4. The resin sealing member 13 holds a first bearing member 15 configured to rotatably support an end portion of the rotating shaft 5 of the rotor 10 on the opposite-output side L2. The cover member 14 holds a second bearing member 16 configured to rotatably support a middle portion of the rotating shaft 5. An end portion of the rotating shaft 5 on the output side L1 protrudes from the housing 12 of the motor 2 into the pump chamber 4, and is attached with the impeller 6.
As shown in
The rotor 10 includes a first bearing plate 45 arranged on the opposite-output side L2 of the holding member 21, and a second bearing plate 46 arranged on the output side L1 of the holding member 21. The first bearing plate 45 and the second bearing plate 46 are substantially circular ring-shaped metal plates. For example, the first bearing plate 45 and the second bearing plate 46 are metal washers. The first bearing plate 45 covers an end surface of the holding member 21 on the opposite-output side L2 in a state in which the rotating shaft 5 penetrates a center hole of the first bearing plate 45. Further, the second bearing plate 46 covers an end surface of the holding member 21 on the output side L1 and the E-ring 24 in a state in which the rotating shaft 5 penetrates a center hole of the second bearing plate 46. The second bearing plate 46 makes surface contact with the E-ring 24. The first bearing plate 45 and the second bearing plate 46 are respectively held by the end surface of the holding member 21 on the opposite-output side L2 and the end surface of the holding member 21 on the output side L1. Sliding heat generated by sliding of the second bearing plate 46 and the second bearing member 16 during rotation of the rotor 10 is transmitted to the rotating shaft 5 through the E-ring 24, and is dissipated.
The stator core 51 is a laminated core formed by laminating thin magnetic plates made of a magnetic material. As shown in
The insulator 52 is made of an insulating material such as resin. The insulator 52 is in a flanged tubular shape having flange portions at both ends in the radial direction. The insulator 52 is attached to each of the plurality of salient pole portions 57. The coil 53 is wound around each of the plurality of salient pole portions 57 through the insulator 52. The insulator 52 partially covers an opposite-output-side end surface 56a (see
The coil 53 is formed of a conductive wire 55 made of aluminum alloy or copper alloy. In the present embodiment, a conductive wire 55, in which aluminum alloy is covered with copper alloy, is used. Further, in the present embodiment, the number of salient pole portions 57, the number of insulators 52 and the number of coils 53 are each nine. The motor 2 is a three-phase brushless motor. Three of nine coils 53 are U-phase coils 53U, three of the remaining six coils 53 are V-phase coils 53V, and the remaining three coils 53 are W-phase coils 53W. The U-phase coils 53U, the V-phase coils 53V, and the W-phase coils 53W are arranged in this order in the circumferential direction. Note that other arrangements may be employed.
Three U-phase coils 53U are formed by sequentially winding the single conductive wire 55 around three salient pole portions 57. Three V-phase coils 53V are formed by sequentially winding the single conductive wire 55 around three salient pole portions 57. Three W-phase coils 53W are formed by sequentially winding the single conductive wire 55 around three salient pole portions 57. Three conductive wires 55 forming the U-phase coils 53U, the V-phase coils 53V, and the W-phase coils 53W are drawn to the connector 54. The U-phase coils 53U, the V-phase coils 53V, and the W-phase coils 53W are respectively connected to the connector 54 through the conductive wire 55.
Inner peripheral edges of the core outer side surface covering portions 52a, 52b are in a linear shape orthogonal to a center line Q (see
As shown in
As shown in
For example, the jumper wire 55U extending over one U-phase coil 53U and another U-phase coil 53U is drawn to the outer peripheral side from the gap S1 provided at the insulator 52 around which the U-phase coil 53U is wound, is hooked on one (for example, the wall portion 59 on the side of the adjacent V-phase coil 53V) of two wall portions 59, and is drawn to the side of the adjacent insulator 52 on the outside of the wall portion 59 in the radial direction. Then, the jumper wire 55U is guided by four wall portions 59 provided at two insulators 52 provided with the V-phase coil 53V and the W-phase coil 53W, and is drawn to the insulator 52 provided with the other U-phase coil 53U. Then, the jumper wire 55U is hooked on the wall portion 59 (for example, the wall portion 59 on the side of the W-phase coil 53W) provided on the insulator 52 provided with the other U-phase coil 53U, and is drawn from the gap S1 to the side of the U-phase coil 53U.
A pushed portion 60 formed in such a manner that the conductive wire 55 is pushed to an inner peripheral side of the wall portion 59 is formed at the jumper wire 55U extending between one U-phase coil 53U and another U-phase coil 53U. As described above, two wall portions 59 spaced apart in the circumferential direction are provided at each of the insulators 52, and a loosened section of the jumper wire 55U is pushed inward of the wall portions 59 in the radial direction from the gap S1 between these two wall portions 59 to form the pushed portion 60. The loosened section of the jumper wire 55U is pushed into the gap S1 to form the pushed portion 60, and therefore, looseness of the jumper wire 55U is suppressed. Thus, expansion of the jumper wire 55U to the outer peripheral side can be suppressed. In the present embodiment, two gaps S1 are present between one U-phase coil 53U and the other U-phase coil 53U, and therefore, the pushed portions 60 are formed at two locations.
The jumper wires 55V, 55W are drawn in the same shape as that of the jumper wire 55U. That is, each of the jumper wires 55V, 55W is drawn from the gap S1 to the outer peripheral side, is hooked on the wall portion 59, is drawn to the outside of the wall portion 59 in the radial direction, is guided by the wall portion 59, and is drawn in the circumferential direction on the outside of the wall portion 59 in the radial direction. Moreover, when each of the jumper wires 55V, 55W passes through two insulators 52, the pushed portions 60 are formed at two locations. Then, each of the jumper wires 55V, 55W is hooked on the wall portion 59 formed at the insulator 52 provided with the other coil 53 of the same phase, and is drawn from the gap S1 to the side of the coil 53.
As shown in
The shape of each of the wall portions 58 varies depending on the angular position of the insulator 52. That is, the wall portion 58 includes three types of: first wall portions 58A formed at two insulators 52A located on the opposite side to the connector 54 in the radial direction; second wall portions 58B formed at two insulators 52B adjacent, in the circumferential direction, to the insulator 52 at the same angular position as that of the connector 54; and third wall portions 58C formed at other four insulators 52C. The third wall portion 58C is in the same shape as that of the above-described wall portion 59 standing toward the output side L1. That is, each of four insulators 52 includes two third wall portions 58C spaced apart in the circumferential direction, and also includes a gap S2 formed between these two wall portions 58C.
As shown in
The second wall portions 58B are provided at the insulators 52B adjacent to the connector 54 in the circumferential direction. Each of the second wall portions 58B is a conductive wire guide portion configured to guide the conductive wire 55 drawn from the coil 53 to the connector 54. The second wall portion 58B is in the form of a flat plate orthogonal to the center line Q of the insulator 52B in the circumferential direction, and an edge thereof on a first side (i.e., the side of the connector 54) in the circumferential direction is closer to the center line Q than an edge thereof on a second side. That is, the second wall portion 58B is not in a symmetrical shape in the circumferential direction with respect to the center line Q, but is in such a shape that the edge on the side of the connector 54 is cut off. As shown in
In the present embodiment, when the stator 11 is arranged in a mold and the resin sealing member 13 is formed, pressing pins 18 (see
As described later, in the present embodiment, six pressing pins 18 are used. The resin sealing member 13 is provided with six holes 17 (see
The holes 17 as the arrangement marks of six pressing pins 18 are provided at angular positions coincident with the centers of the insulators 52 in the circumferential direction. At the insulator 52A provided with the first common wire support portions 62, the second common wire support portion 63 connected to the first common wire support portions 62 is arranged at an angular position (the center in the circumferential direction) at which the hole 17 is formed. By providing the second common wire support portion 63 at the angular position at which the pressing pin 18 is provided as described above, the common wire 55A can be supported so as not to protrude to the side of the pressing pin 18. Thus, contact between the pressing pin 18 and the common wire 55A can be prevented. Further, for example, a situation where disconnection of the common wire 55A occurs due to the common wire 55A being caught between the pressing pin 18 and the insulator 52A can be prevented.
Similarly, at the insulator 52B provided with the second wall portion 58B, the second wall portion 58B is arranged at an angular position (the center in the circumferential direction) at which the hole 17 is formed. By providing the second wall portion 58B at the angular position at which the pressing pin 18 is provided as described above, the conductive wire 55 drawn to the connector 54 can be supported so as not to protrude to the side of the pressing pin 18. Thus, contact between the pressing pin 18 and the conductive wire 55 can be prevented. Further, for example, a situation where disconnection of the conductive wire 55 occurs due to the conductive wire 55 being caught between the pressing pin 18 and the insulator 52B can be prevented.
As shown in
The first common wire support portion 62 is in a shape extending inward in the radial direction as a distance from the third wall portion 58C increases. In other words, the first common wire support portion 62 is in a shape extending inward in the radial direction toward a tip end side of the common wire 55A. In such a shape, the first common wire support portion 62 supports the common wire 55A from the outside in the radial direction. Thus, the common wire 55A is supported in a state in which a tip end thereof faces the inner peripheral side, and a state in which the common wire 55A is less detached from the first common wire support portion 62 is brought. Further, the second common wire support portion 63 connected to the first common wire support portions 62 is arranged on the tip end side of the common wire 55A, and therefore, a tip end portion of the common wire 55A is supported so as not to protrude to the outside of the stator 11 in the radial direction. That is, the common wire 55A is temporarily fixed to the insulator 52. By forming the resin sealing member 13 in this state, protrusion of the common wire 55A outward in the radial direction from the stator 11 is prevented.
The connector 54 is in such a shape that a male external connector is attachable thereto and detachable therefrom. The connector 54 is connected to one of the plurality of insulators 52. The connector 54 includes a substantially rectangular parallelepiped connector housing 30, a connection portion 31 connecting the connector housing 30 and the insulator 52, and terminal pins 40 held by the connector housing 30. The connector housing 30 is arranged on the outer peripheral side of the insulator 52 and on the opposite-output side L2 of the stator core 51, and is connected to a section (the core outer side surface covering portion 52a) of the insulator 52 located on the outer peripheral side of the coil 53 through the connection portion 31. The connector housing 30 and the connection portion 31 are integrally formed with the insulator 52.
The connector 54 is a female connector 54 including three terminal pins 40 of: the terminal pin 40 to which one end portion of the conductive wire 55 forming the U-phase coil 53U is connected, the terminal pin 40 to which one end portion of the conductive wire 55 forming the V-phase coil 53V is connected, and the terminal pin 40 to which one end portion of the conductive wire 55 forming the W-phase coil 53W is connected.
The connector housing 30 is in a substantially rectangular parallelepiped shape opening to the opposite-output side L2. That is, the connector housing 30 is provided with a connection opening 30a opening to the opposite-output side L2. The connector housing 30 includes a rectangular tubular cylinder portion 33 extending in the direction of the axis L, and a bottom portion 32 closing an end portion of the cylinder portion 33 on the output side L1. The connection opening 30a is provided at an end portion of the cylinder portion 33 on the opposite-output side L2. As shown in
The terminal pin 40 is formed by bending a metal wire having a rectangular cross-sectional shape. Note that, the terminal pin 40 may be formed also by bending a metal wire having a circular cross-sectional shape. As shown in
As shown in
The conductive wire connection portion 42 is a section around which the conductive wire 55 connecting the coil 53 and the terminal pin 40 is wound. The conductive wire connection portion 42 is in a retaining shape allowing detachment of the conductive wire 55 wound around the conductive wire connection portion 42 to be suppressed. The retaining shape of the present embodiment is such a bent shape that the tip end portion (the retaining portion 42a) of the conductive wire connection portion 42 is bent from the section (the linear portion 42b) connected to the tip end portion. The retaining portion 42a is bent such that a tip end thereof faces inward in the radial direction. Note that a bending angle of the retaining portion 42a is not necessarily a substantially right angle. For example, the bending angle may be an obtuse angle.
As shown in
As shown in
The conductive wire 55 is guided by the guide protruding portion 39, is drawn toward the conductive wire connection portion 42, and is drawn to the retaining portion 42a along the linear portion 42b. For the conductive wire 55 drawn along the linear portion 42b, short circuit is prevented by the wall portion 38 arranged between adjacent linear portions 42b. The conductive wire 55 is wound around the linear portion 42b or the retaining portion 42a and soldered to the linear portion 42b or the retaining portion 42a. As described above, the wall portion 38 has the height not reaching the retaining portion 42a, and therefore, soldering can be performed in a state in which a soldering iron is brought close to upper ends of the retaining portion 42a and the linear portion 42b without being interfered by the wall portion 38.
As shown in
A bearing member holding recessed portion 68 is provided at a center section of the sealing member bottom portion 65. The bearing member holding recessed portion 68 holds the first bearing member 15 configured to rotatably support the end portion of the rotating shaft 5 of the rotor 10 on the opposite-output side L2. The first bearing member 15 is made of resin, and is in a shape including a tubular support portion provided with a through-hole in which the rotating shaft 5 is arranged and a flange portion expanding to the outer peripheral side from the end portion of the cylinder portion on the output side L1. The contour of the first bearing member 15 as viewed in the direction of the axis L is a D-shape. The first bearing member 15 is fixed to the bearing member holding recessed portion 68 in a state in which the flange portion contacts the sealing member bottom portion 65 from the output side L1. The first bearing member 15 is configured such that the support portion into which the rotating shaft 5 is inserted functions as a radial bearing of the rotating shaft 5 and the flange portion functions as a thrust bearing of the rotor 10. That is, the first bearing plate 45 fixed to the holding member 21 of the rotor 10 slides on the flange portion of the first bearing member 15.
As shown in
As shown in
The connector 54 is configured such that the end portion of the connector housing 30 having the connection opening 30a to and from which the male connector is attached and detached protrudes from the connector sealing portion 66 to the opposite-output side L2, and is exposed to the outside. The connection opening 30a is provided at a position protruding from the end surface 66d of the connector sealing portion 66 on the opposite-output side L2 by a dimension H (see
As shown in
At an outer peripheral surface of the sealing member cylinder portion 67, a resin-sealing-member-side position control surface 70 as a step surface facing the output side L1 is formed at a boundary between the second small-diameter cylinder section 82b and the large-diameter cylinder section 81. The resin-sealing-member-side position control surface 70 is orthogonal to the direction of the axis L. As described later, the resin-sealing-member-side position control surface 70 is a surface contacting the cover member 14 in the direction of the axis L. Further, the sealing member cylinder portion 67 includes, at the end portion on the output side L1, a resin-sealing-member-side fixing surface 71 as an annular end surface orthogonal to the direction of the axis L. As described later, the resin-sealing-member-side fixing surface 71 faces the cover member 14 with a predetermined gap interposed therebetween. The cover member 14 is fixed to the resin sealing member 13 with an adhesive arranged in the gap between the resin-sealing-member-side fixing surface 71 and the cover member 14.
The outside diameter of the large-diameter cylinder section 81 is larger than the outside diameter of the annular portion 56 of the stator core 51, and the outside diameter of the second small-diameter cylinder section 82b is smaller than the outside diameter of the annular portion 56 of the stator core 51. Further, the resin-sealing-member-side position control surface 70 is located on the same plane as the opposite-output side end surface 56a of the annular portion 56 of the stator core 51. Thus, at an inner peripheral section of the resin-sealing-member-side position control surface 70, a plurality of arc-shaped openings 83 (see
As shown in
Four engagement protruding portions 85 protruding to the outer peripheral side are provided at regular angular intervals at an outer peripheral surface of the large-diameter cylinder section 81. The engagement protruding portions 85 each engage with a rotation engagement portion 86 provided at the cover member 14 as described later. The engagement protruding portion 85 engages with the rotation engagement portion 86 to restrict detachment of the cover member 14 from the resin sealing member 13.
The resin sealing member 13 completely covers the coils 53, and protects the coils 53 from fluid. Further, the resin sealing member 13 is, except for the opening (the connection opening 30a) to and from which the male connector is attached and detached, integrally formed, including the connector sealing portion 66 covering the connector 54, and therefore, the resin sealing member 13 prevents detachment of the terminal pins 40 assembled to the connector 54, and protects each connection portion between the terminal pin 40 and the conductive wire 55 from fluid. The resin sealing member 13 is made of a bulk molding compound (BMC). In the present embodiment, the stator 11 is arranged in the mold, and a resin material is injected into the mold and is cured. In this manner, the resin sealing member 13 is formed. That is, the resin sealing member 13 is integrally formed with the stator 11 by insert molding.
When insert molding is performed, resin is injected into the mold to form the resin sealing member 13 in a state in which the stator core 51 arranged in the mold is brought into contact with the mold in the radial direction and the direction of the axis L and is positioned. Accordingly, the accuracy of relative positions of the stator core 51 and the resin sealing member 13 is improved. For example, a columnar mold section is provided in the mold, and an outer peripheral surface of the mold section is brought into contact with the inner peripheral end surface 57a of each salient pole portion 57 to position the stator core 51 in the radial direction. As a result, the inner peripheral end surface 57a of each salient pole portion 57 of the stator core 51 is exposed through the resin sealing member 13 as described above. Alternatively, when insert molding is performed, a first contact section contactable with the output-side end surface 57b of each salient pole portion 57 and a second contact section contactable with the output-side end surface 56b of the annular portion 56 are provided in the mold, and these first and second contact sections are brought into contact with the stator core 51 to position the stator core 51 in the direction of the axis L. As a result, part of the output-side end surface 57b of each salient pole portion 57 of the stator core 51 is exposed to the output side L1 as described above. Further, an outer peripheral section of the output-side end surface 56b of the annular portion 56 is exposed to the output side L1.
As shown in
The cover member 14 is made of resin, and is fixed to the output side L1 of the resin sealing member 13. The cover member 14 includes a discoid cover-member ceiling portion 91 and a cover-member cylinder portion 92 protruding from the cover-member ceiling portion 91 to the opposite-output side L2. At the center of the cover-member ceiling portion 91, a through-hole 93 penetrating in the direction of the axis L is provided. A circular recessed portion 94 surrounding the through-hole 93 is provided at the center of a surface of the cover-member ceiling portion 91 on the output side L1, and a circular ring-shaped seal member 95 is arranged at the circular recessed portion 94. The seal member 95 is arranged in a gap between the rotating shaft 5 and the cover member 14.
As shown in
As shown in
The inner annular rib 99 and the radial ribs 98, 96 are protruding portions protruding to the opposite-output side L2. Further, the first adhesive reservoir portions 100 are each a recessed portion more recessed toward the output side L1 than the cover-member-side fixing surface 72 and the radial rib 98. The first adhesive reservoir portion 100 is a recessed portion utilizing the thin-walled shape of the cover member 14. That is, the first adhesive reservoir portion 100 also forms the thin-walled shape of the cover member 14. Further, on the inner peripheral side of the inner annular rib 99, a recessed portion in a thin-walled shape is also formed between the radial ribs 96.
As shown in
The cover member cylinder portion 92 includes an upper annular cylinder section 92d overlapping with the small-diameter cylinder section 82 of the resin sealing member 13 in the direction of the axis L and covering the small-diameter cylinder section 82 of the resin sealing member 13 from the outer peripheral side, and a lower annular cylinder section 92e located on the outer peripheral side of the large-diameter cylinder section 81 of the resin sealing member 13. The upper annular cylinder section 92d is a section on the output side L1 with respect to the cover-member-side position control surface 73. Further, the lower annular cylinder section 92e is a protruding portion protruding to the opposite-output side L2 with respect to the cover-member-side position control surface 73 and covering the outer peripheral side of the resin sealing member 13. As shown in
The cover member 14 covers the resin sealing member 13 from the output side L1 in a state in which the rotor 10 is arranged on the inside of the resin sealing member 13 and the rotor 10 is supported by the first bearing member 15. When the cover member 14 covers the resin sealing member 13, a lower end portion of the inner annular rib 99 is, as shown in
The cover member 14 is positioned in the direction of the axis L by contact, in the direction of the axis L, between the cover-member-side position control surface 73 provided at the cover member cylinder portion 92 and the resin-sealing-member-side position control surface 70 as the step surface provided at an outer peripheral surface of the resin sealing member 13. Accordingly, the cover-member ceiling portion 91 covers the rotor 10 and the resin sealing member 13 from above with the rotating shaft 5 penetrating in an up-down direction. Further, the seal member 95 arranged in the circular recessed portion 94 of the cover-member ceiling portion 91 seals between the rotating shaft 5 and each of the cover member 14 and the second bearing member 16. In addition, the cover member cylinder portion 92 surrounds a section of the resin sealing member 13 on the output side L1 from the outer peripheral side. Thereafter, the cover member 14 and the resin sealing member 13 are rotated relative to each other in the circumferential direction, and as shown in
When the cover member 14 covers the resin sealing member 13, an adhesive is applied to the resin-sealing-member-side fixing surface 71 (see
The first adhesive reservoir portion 100 is provided at a position adjacent to the cover-member-side fixing surface 72 on the inner peripheral side. Thus, an excessive adhesive overflowing to the inner peripheral side of the cover-member-side fixing surface 72 is held by the first adhesive reservoir portion 100. Further, the cover member 14 includes a second adhesive reservoir portion 101 provided between the cover-member-side fixing surface 72 and the cover-member-side position control surface 73. Thus, an excessive adhesive overflowing to the outer peripheral side from the cover-member-side fixing surface 72 is held by the second adhesive reservoir portion 101.
As described above, the motor 2 and the pump device 1 of the present embodiment include the common wire 55A connecting the conductive wires 55 drawn from the coils 53 of each phase, and the first common wire support portions 62 supporting the common wire 55A from the outside in the radial direction are formed at the insulator 52. The first common wire support portions 62 are each in the shape extending inward in the radial direction toward the tip end side of the common wire 55A, and therefore, protrusion of the common wire 55A to the outer peripheral side of the first common wire support portions 62 can be suppressed. Thus, exposure of the common wire 55A to the outer peripheral side of the stator 11 can be suppressed.
In the present embodiment, the stator 11 is configured so that the common wire 55A can be temporarily fixed to the insulator 52 with the common wire 55A being held by the first common wire support portions 62. Thus, in a case where the stator 11 is sealed with the resin sealing member 13, the common wire 55A can be held so as not to protrude to the outside of the resin sealing member. Thus, the common wire 55A can be insulated. Further, the first common wire support portions 62 are integrally formed with the insulator 52, and therefore, another component for suppressing protrusion of the common wire 55A is not necessarily used. Thus, an increase in the number of components can be suppressed.
In the present embodiment, the insulator 52 provided with the first common wire support portions 62 includes the second common wire support portion 63 connected to the end portions of the first common wire support portions 62, the end portions being on the inner side in the radial direction, and can support the tip end portion of the common wire 55A by the second common wire support portion 63. Thus, exposure of the common wire 55A to the outer peripheral side of the stator 11 can be suppressed. Further, the third wall portion 58C configured to guide the common wire 55A to the insulator 52 adjacent, in the circumferential direction, to the insulator 52 provided with the first common wire support portions 62 is provided, and therefore, the common wire 55A can be drawn to the first common wire support portions 62. In addition, the first common wire support portion is provided at a single location on each end side of the insulator in the circumferential direction, and therefore, the common wire 55a can be supported regardless of whether the direction of drawing the common wire is a first side or a second side in the circumferential direction.
In the present embodiment, when the resin sealing member 13 covering the stator 11 is formed, the pressing pins 18 configured to press the stator 11 in the direction of the axis L against the mold are used. Thus, the resin sealing member 13 is provided with the holes 17 as the arrangement marks of the pressing pins 18. The second common wire support portion 63 is arranged in an angular range including the angular position of the hole 17. Accordingly, the common wire 55A can be supported so as not to protrude to the pressing pin side, contact between the pressing pin 18 and the common wire 55A can be prevented by the second common wire support portion 63. Thus, disconnection of the common wire 55A due to the common wire 55A being caught between the pressing pin 18 and the insulator 52 can be prevented.
In the present embodiment, the insulator 52 adjacent, in the circumferential direction, to the insulator 52 connected to the connector 54 includes the conductive wire guide portion (the second wall portion 58B) configured to guide the conductive wire 55 drawn from the coil 53 to the connector 54. The second wall portion 58B is a single continuous wall portion, and is arranged in an angular range including the angular position of the hole 17. Thus, contact between the pressing pin 18 and the common wire 55A can be prevented by the second wall portion 58B. Thus, disconnection of the common wire 55A due to the common wire 55A being caught between the pressing pin 18 and the insulator 52 can be prevented.
In the present embodiment, the jumper wire guide portions (the wall portions 59) configured to guide the jumper wires 55U, 55V, 55W connecting the coils 53 of the same phase are provided at the insulator 52, and therefore, the jumper wires 55U, 55V, 55W can be drawn in an appropriate path. Further, the pushed portion 60 pressed into the gap S1 between two wall portions 59 spaced apart in the circumferential direction is formed at each of the jumper wires 55U, 55V, 55W, and therefore, looseness of the jumper wires 55U, 55V, 55W can be suppressed. Thus, expansion of the jumper wires 55U, 55V, 55W to the outer peripheral side can be suppressed.
While the description above refers to particular embodiments of the present invention, it will be understood that many modifications may be made without departing from the spirit thereof. The accompanying claims are intended to cover such modifications as would fall within the true scope and spirit of the present invention.
The presently disclosed embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims, rather than the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.
Number | Date | Country | Kind |
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2017-024969 | Feb 2017 | JP | national |
This is the U.S. national stage of application No. PCT/JP2018/004141, filed on Feb. 7, 2018. Priority under 35 U.S.C. § 119(a) and 35 U.S.C. § 365(b) is claimed from Japanese Application No. 2017-024969, filed Feb. 14, 2017; the disclosures of which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/004141 | 2/7/2018 | WO | 00 |