JP5212147B2 - Electric pump unit - Google Patents

Description

  The present invention relates to an electric pump unit used as a hydraulic pump for supplying hydraulic pressure to a transmission of an automobile, for example.

  In recent years, as a hydraulic pump for automobiles, it has been designed to save energy by finely controlling its start and stop, and to ensure the supply of hydraulic pressure to the drive system such as the transmission even when the engine is stopped due to idling stop In addition, an electric pump unit is used.

  Since the electric pump unit for automobiles is mounted in a limited space of the vehicle body, downsizing is required, and weight reduction and cost reduction are also required. As an electric pump unit that meets this requirement, an electric pump unit in which a pump, an electric motor for driving a pump, and a controller for the motor are integrally incorporated in a common unit housing has been proposed (for example, see Patent Document 1).

JP 2008-151065 A

  In the electric pump unit described above, a suction port and a discharge port are formed in the pump plate that closes the pump chamber and communicates the pump chamber with the outside.

  The pump unit may be attached directly to the transmission. In this case, the outer end face of the pump port is attached to the end face of the transmission in which the suction hole corresponding to the suction port and the discharge hole corresponding to the discharge port are formed.

  The shape and position of the suction port and the discharge port in the electric pump unit are determined by the specifications of the electric pump. On the other hand, the positions of the suction hole and the discharge hole in the transmission are determined by the specifications of the transmission. For this reason, when the type of transmission is changed, the relative position between the suction port and the suction hole and the relative position between the discharge port and the discharge hole may be shifted, which may hinder oil flow.

  To avoid this, it is necessary to use a dedicated pump plate having a different configuration depending on the type of transmission. In some cases, it is not possible to cope with the problem by simply changing the configuration of the pump plate, and it is necessary to change the configuration of the pump in the electric pump unit. For this reason, the parts cannot be shared, which leads to an increase in cost.

  The same problem occurs in the case of an electric pump unit that supplies hydraulic pressure other than the transmission of an automobile.

  The object of the present invention is to solve the above-mentioned problems, without causing any trouble in the oil flow even if the positions of the suction port and the discharge port do not coincide with the positions of the suction hole and the discharge hole of the target device. An object of the present invention is to provide an electric pump unit capable of sharing parts.

  In the electric pump unit according to the present invention, the pump plate closing the pump chamber of the pump driven by the electric motor is formed with a suction port and a discharge port communicating with the pump chamber and the outside, and the outer end surface of the pump plate is sealed. In the electric pump unit that is attached to the end face of the target device in which the suction hole and the discharge hole are formed through the member, the suction port is communicated over a wider range than the suction port by removing the periphery of the suction port on the outer end face of the pump plate. Is formed, and the periphery of the discharge port is removed to form a discharge hole communication part that covers a wider area than the discharge port. The periphery of the suction hole communication part and the periphery of the discharge hole communication part are sealed with a sealing member. It is characterized by being.

  The target device refers to a device to which hydraulic pressure is supplied from the electric pump unit, that is, a device to be supplied with hydraulic pressure.

  When the electric pump unit is attached to the target device, the suction port of the pump plate communicates with the suction hole of the target device via the suction hole communicating portion, and the discharge port of the pump plate communicates with the target device via the discharge hole communicating portion. The seal member communicates with the discharge hole and presses against the end face of the target device. Since the suction hole communication section covers a wider area than the suction port, even if the suction port and the suction hole are misaligned, the oil flow will be hindered as long as the entire suction hole communicates with the suction hole communication section. There is nothing. Similarly, since the discharge hole communication part covers a wider range than the discharge port, even if the position of the discharge port and the discharge hole is misaligned, as long as the entire discharge hole is in communication with the discharge hole communication part, the flow of oil is prevented. There will be no hindrance. For this reason, the range of the position of the suction hole and the discharge hole of the target device that can be used is widened, and parts such as the pump plate can be shared.

  For example, an annular seal member that seals the periphery of the suction hole communication portion and a seal member that seals the periphery of the discharge hole communication portion are provided separately. A seal member may be used that includes an annular portion that surrounds a portion including the suction hole communication portion and the discharge hole communication portion, and a connecting portion that is integrally connected to the annular portion at both ends and located between the two communication portions. For example, the seal member is fitted into a groove formed on the end face of the pump plate.

  In the electric pump unit according to the present invention, for example, the suction hole communication portion and the discharge hole communication portion are separated by a linear partition wall portion, and the suction member communication portion and discharge port except for the portion where the seal member faces the partition wall portion. The annular portion is arranged around the hole communicating portion, and the both ends are integrally connected to the annular portion and are connected to the partition portion.

  In this way, the suction hole communication portion and the discharge hole communication portion can be made wider, and the range of the position of the suction hole and the discharge hole of the target device that can be used can be made wider. Moreover, the circumference | surroundings of the suction hole communication part and the discharge hole communication part can be sealed with one seal member.

  For example, an annular groove surrounding a portion including the suction hole communication portion and the discharge hole communication portion is formed on the outer end surface of the pump plate, and a communication groove communicating with the annular groove is formed on the end surface of the partition wall. It fits into these grooves and is brought into pressure contact with the end face of the target device.

  In the electric pump unit described above, for example, grooves are formed on the end surface of the pump plate around the suction hole communication portion excluding the portion facing the partition wall and on both ends of the partition wall, and the annular portion of the seal member It is arrange | positioned in the circumference | surroundings in a discharge hole communication part except the part which faces a part, and in a groove | channel, and the connection part of a sealing member is arrange | positioned in the part which touches the partition part in a discharge hole communication part.

  When the pump is operating, the pressure in the suction port and the suction hole communication portion is smaller than the atmospheric pressure, and the pressure in the discharge port and the discharge hole communication portion is larger than the atmospheric pressure. The portion of the seal member located in the discharge hole communication portion is not fitted in the groove, but is urged outward by a large pressure in the discharge hole communication portion, and is pressed against the peripheral wall of the partition wall portion and the discharge hole communication portion, so that the discharge hole Securely seal around the communication part. On the other hand, although the suction hole communicating portion has a negative pressure, the portion of the seal member around the suction hole communicating portion is securely held by the partition wall and the groove, and the periphery of the suction hole communicating portion is surely sealed.

  In this case, the number of grooves for holding the seal member can be minimized.

  In the electric pump unit described above, for example, the suction hole communication portion and the discharge hole communication portion have a semicircular shape, and the combined portion of both the communication portions has a circular shape.

  In this case, the seal member has a simple shape in which circular annular portions are connected by a connecting portion.

  The seal member is, for example, an O-ring.

  According to the electric pump unit of the present invention, as described above, even if the positions of the suction port and the discharge port do not coincide with the positions of the suction hole and the discharge hole of the target device, the oil flow is hindered. The parts can be shared and the cost can be reduced.

FIG. 1 is a longitudinal sectional view of an electric pump unit showing an embodiment of the present invention. 2 is a cross-sectional view taken along line II-II in FIG.

  Hereinafter, an embodiment in which the present invention is applied to an electric pump unit used for a hydraulic pump of an automobile will be described with reference to the drawings.

  FIG. 1 is a longitudinal sectional view of an electric pump unit showing an embodiment of the present invention, and FIG. 2 is a sectional view taken along line II-II in FIG. In the following description, the left side of the drawing is the front and the right side is the rear.

  The electric pump unit is a unit housing (1) in which a pump (2) and an electric motor (3) for rotationally driving the pump (2) are integrated. The controller (4) of the motor (3) is also incorporated in the housing (1). In this example, the pump (2) is a trochoid pump, and the motor (3) is a DC brushless sensorless motor having a three-phase winding.

  The unit housing (1) consists of a pump housing (5), pump plate (6), motor housing (7) and lid (8), and is waterproof by the pump housing (5), motor housing (7) and lid (8). A housing (9) is constructed.

  The pump housing (5) has a thick plate shape that extends in a direction perpendicular to the front-rear direction, and a pump chamber (10) having an open front is formed at the center thereof. A pump plate (6) is fixed to the front surface of the pump housing (5) via an O-ring (11), and the front surface of the pump chamber (10) is closed. An outer gear (12) constituting the pump (2) is rotatably accommodated in the pump chamber (10), and an inner gear (13) that meshes with the inner gear (12) is disposed inside the outer gear (12).

  The motor housing (7) has a cylindrical shape, and its front end is fixed to a portion near the outer periphery of the rear surface of the pump housing (5) via a seal (14). The rear end opening of the motor housing (7) is closed by the lid (8).

  A cylindrical portion (5a) having a smaller diameter than the motor housing (7) is integrally formed at the center of the rear end surface of the pump housing (5), and a bearing device (15) provided at the rear portion in the cylindrical portion (5a) A pump drive motor shaft (16) extending in the front-rear direction is cantilevered. In this example, the bearing device (15) includes two ball bearings (17) that are adjacent to the front and rear, and the inner ring (17a) of each bearing (17) is fixed to the motor shaft (16). The outer ring (17b) is fixed to the cylindrical portion (5a). The front part of the motor shaft (16) passes through the hole (18) formed in the rear wall of the pump housing (5) and enters the pump chamber (10), and the front end of the motor shaft (16) reaches the inner gear (13). It is connected. A seal (19) is provided between a portion of the cylindrical portion (5a) in front of the bearing device (15) and the motor shaft (16).

  A motor rotor (20) constituting the motor (3) is fixed to a rear end portion of the motor shaft (16) protruding rearward from the cylindrical portion (5a). The rotor (20) has a cylindrical shape extending in the radial direction from the rear end of the motor shaft (16) and surrounding the outer periphery of the bearing device (15), and a permanent magnet (21) is provided on the outer periphery. The axial position of the center of gravity of the rotating portion including the motor shaft (16), the rotor (20), and the inner gear (13) of the pump (2) is within the axial range of the bearing device (15). In this example, the axial position of the center of gravity is between the two ball bearings (17) constituting the bearing device (15).

  A motor stator (22) constituting the motor (3) is fixedly provided on the inner periphery of the motor housing (7) facing the rotor (20). In the stator (22), an insulator (synthetic resin insulator) (24) is incorporated in a core (23) made of laminated steel plates, and a coil (25) is wound around the insulator (24). In this example, the stator (22) is fixed to the inner periphery of the motor housing (7) by an appropriate means such as adhesion on the outer periphery of the core (23).

  The board (26) of the controller (4) is fixed to the rear end of the insulator (24), and a component (27) constituting the controller (4) is attached to the board (26). The component is disposed at a predetermined position on at least one of the front surface and the rear surface of the substrate (26). In the drawing, one component (27) attached to the rear surface of the substrate (26) is shown.

  Although the detailed illustration is omitted, the pump plate (6) is attached to the end surface (28a) of the transmission (28) as a target device by a plurality of bolts, and the outer end surface (6a) of the pump plate (6) is the transmission end surface ( 28a).

  A suction port (29) and a discharge port (30) communicating with the pump chamber (10) and the outside are formed in the pump plate (6) in a penetrating manner, and the transmission end surface (28a) is connected to the suction port (29). A suction hole (31) communicating with the discharge port (30) and a discharge hole (32) communicating with the discharge port (30) are formed. The suction port (29) and the discharge port (30) form an arc shape.

  At the pump plate end surface (6a), the periphery of the suction port (29) is removed to form a suction hole communication portion (29a) that covers a wider area than the suction port (29), and the periphery of the discharge port (30) is removed. Accordingly, a discharge hole communication portion (30a) that is wider than the discharge port (30) is formed. The suction port (29) communicates with the suction hole (31) via the suction hole communication portion (29a), and the discharge port (30) communicates with the discharge hole (32) via the discharge hole communication portion (30a). Communicate.

  The pump port (6) is fitted with an O-ring (33), which is a seal member that presses against the transmission end face (28a) and seals the periphery of the suction hole communication part (29a) and the periphery of the discharge hole communication part (30a) It has been. The depths of both communicating portions (29a) and (30a) from the pump plate end face (6a) are slightly smaller than the diameter in the natural state of an elastic material such as rubber constituting the O-ring (33).

  Both communicating portions (29a) and (30a) are formed in a semicircular shape having substantially the same size, leaving a linear partition wall portion (34) separating them, and both communicating portions (29a) (30a) The combined part forms a circle. A semicircular groove (35) is formed at both ends of the pump plate end surface (6a) and the partition wall portion (34) around the suction hole communication portion (29a) excluding the portion facing the partition wall portion (34). .

  The O-ring (33) has a simple shape composed of a circular annular portion (33a) and a connecting portion (33b) in which both ends are integrally connected to a substantially symmetrical position of the annular portion (33a). The annular portion (33a) of the seal member (33) is disposed around the discharge hole communicating portion (30a) excluding the portion facing the partition wall portion (34) and in the groove (35), and the seal member (33) The connecting portion (33b) is disposed at a portion in contact with the partition wall portion (34) in the discharge hole communicating portion (30a). When the pump plate (6) is not attached to the transmission end face (28a), a part of the O-ring (33) protrudes slightly from the pump plate end face (6a), and the pump plate (6) is attached to the transmission end face. When attached to (28a), the O-ring (33) is pressed against the transmission end face to seal the periphery of the suction hole communicating portion (29a) and the periphery of the discharge hole communicating portion (30a).

  When the pump (2) is operating, the pressure in the suction port (29) and the suction hole communication part (29a) is smaller than atmospheric pressure, and the pressure in the discharge port (30) and the discharge hole communication part (30a) is Greater than atmospheric pressure. The portion of the seal member (33) located in the discharge hole communication portion (30a) is not fitted in the groove, but is urged outward by a large pressure in the discharge hole communication portion (30a), and the partition wall portion (34) In addition, the periphery of the discharge hole communication portion (30a) is securely sealed by being pressed against the peripheral wall of the discharge hole communication portion (30a). On the other hand, the suction hole communication part (29a) has a negative pressure, but the seal member (33) around the suction hole communication part (29a) is securely held by the partition wall part (34) and the groove (35). Thus, the periphery of the suction hole communicating portion (29a) is securely sealed.

  In the electric pump unit described above, since the suction hole communication portion (29a) is wider than the suction port (29), even if the positions of the suction port (29) and the suction hole (31) are shifted, the suction hole ( 31) As long as the whole communicates with the suction hole communication part (29a), the oil flow will not be hindered. Similarly, the discharge hole communicating portion (30a) covers a wider range than the discharge port (30), so even if the positions of the discharge port (30) and the discharge hole (32) are misaligned, the entire discharge hole (32) As long as it communicates with the discharge hole communicating portion (30a), it does not hinder the oil flow. For this reason, the range of the positions of the suction hole (31) and the discharge hole (32) of the end surface (28a) of the transmission (28) that can be used is widened, and parts such as the pump plate (6) can be shared.

  In the electric pump unit, one axial position of the motor shaft (16) is cantilevered by the bearing device (15), and the motor rotor (20) is provided so as to surround the outer periphery of the bearing device (15). Because of the structure, the length of the motor shaft (16) can be shortened, and further downsizing is possible. Further, since the axial position of the center of gravity of the rotating part including the motor shaft (16), the motor rotor (20) and the inner gear (13) of the pump (2) is within the axial range of the bearing device (15), the rotating part Can be stably rotated. Furthermore, since the position of the center of gravity in the axial direction is between the two ball bearings (17) constituting the bearing device (15), the rotating part can be supported in a more stable manner. Further, the bearing device (15) can be supported only by the cylindrical portion (5a) formed integrally with the pump housing (5), and no other member for supporting the bearing device (15) is required. For this reason, the number of parts can be further reduced, and further weight reduction and cost reduction are possible.

  The overall configuration of the electric pump unit and the configuration of each unit are not limited to those of the above-described embodiment, and can be changed as appropriate.

  For example, in the above embodiment, the bearing device is configured by a rolling bearing, but the bearing device may be configured by a slide bearing.

  Moreover, this invention is applicable also to electric pump units other than the electric pump unit for motor vehicles.

(2) Pump
(3) Electric motor
(6) Pump plate
(6a) Outer end face of pump plate
(10) Pump room
(28) Transmission (target device)
(28a) End face of transmission
(29) Suction port
(29a) Suction hole communication part
(30) Discharge port
(30a) Discharge hole communication part
(31) Suction hole
(32) Discharge hole
(33) O-ring (seal member)
(33a) O-ring annular part
(33b) O-ring connection
(34) Bulkhead
(20) Rotor
(21) Permanent magnet
(28) Rotor body
(29) Permanent magnet holding member
(30) Non-rotating recess
(31) Torus
(32) Connecting part
(33) Non-rotating convex
(34) Rod-shaped part
(35) Groove

Claims (3)

The pump plate that closes the pump chamber of the pump driven by the electric motor is formed with a suction port and a discharge port that communicate with the pump chamber and the outside, and the outer end surface of the pump plate is connected to the suction hole and the In the electric pump unit attached to the end face of the target device in which the discharge hole is formed,
At the outer end face of the pump plate, the periphery of the suction port is removed to form a suction hole communication portion that is wider than the suction port, and the periphery of the discharge port is removed to provide a discharge hole communication portion that is wider than the discharge port. An electric pump unit that is formed, and the periphery of the suction hole communication portion and the periphery of the discharge hole communication portion are sealed with a seal member.   The suction hole communication portion and the discharge hole communication portion are separated by a linear partition wall, and the seal member is annularly disposed around the suction hole communication portion and the discharge hole communication portion excluding the portion facing the partition wall. The electric pump unit according to claim 1, wherein the electric pump unit is composed of a portion and a connecting portion having both ends integrally connected to the annular portion and disposed in the partition wall. A discharge hole is formed in which the groove is formed in the end surface of the pump plate around the suction hole communicating portion excluding the portion facing the partition and the both ends of the partition, and the annular portion of the seal member excludes the portion facing the partition 3. The electric pump unit according to claim 2 , wherein the electric pump unit is disposed around the communication portion and in the groove, and the connecting portion of the seal member is disposed at a portion in contact with the partition wall portion in the discharge hole communication portion.

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