Electric-power control device, electric motor, air-conditioning apparatus, and method for manufacturing electric motor

1 . An electric-power control device which drives an electric motor including a rotor into which a rotation shaft is inserted and a stator provided on an outer peripheral side of the rotor, the electric-power control device comprising: an annular substrate including a through hole through which the rotation shaft passes, the substrate being provided to face the rotor and the stator; a connector which is provided at a peripheral portion of the substrate, and to which a lead wire is connected; a power semiconductor module mounted on a first region which is one of sides of the substrate which are divided with respect to a straight line connecting a center of the through hole to a center of the connector, the power semiconductor module including a ground terminal and a driving circuit; and a microcomputer mounted on a second region which is an other of the sides of the substrate, the microcomputer including a ground terminal and being configured to control electric power to be supplied to the electric motor, on the substrate, a first ground pattern portion, a second ground pattern portion and a connection portion being provided, the first ground pattern portion being provided as a ground electrode which is connected to the ground terminal of the power semiconductor module, and formed to extend from the power semiconductor module toward the connector in the first region, the second ground pattern portion being provided as a ground electrode which is separated from the first ground pattern portion, connected to the ground terminal of the microcomputer, and formed to extend from the microcomputer toward the connector in the second region, the connection portion connecting part of the first ground pattern portion that is close to the connector and part of the second ground pattern portion that is close to the connector. 2 . The electric-power control device of claim 1 , wherein the connection portion is a ground electrode provided on the substrate, and wherein the connection portion is formed narrower than the first ground pattern portion and the second ground pattern portion. 3 . The electric-power control device of claim 2 , wherein the connection portion and the connector are separated from each other by a distance which is shorter than a distance between the through hole and the connector. 4 . The electric-power control device of claim 1 , wherein the lead wire includes a first lead wire connected to the first ground pattern portion, and a second lead wire connected to the second ground pattern portion, and wherein the connection portion is provided outside the substrate, and connects the first ground pattern portion and the second ground pattern portion, with the first lead wire and the second lead wire interposed between the connection portion and the first ground pattern portion and the second ground pattern portion. 5 . The electric-power control device of claim 4 , wherein the connection portion is a ground electrode provided on a control substrate of an apparatus incorporating the electric motor. 6 . The electric-power control device of claim 5 , wherein the connection portion is formed narrower than the first ground pattern portion and the second ground pattern portion. 7 . The electric-power control device of claim 1 , wherein the microcomputer and the connector are separated from each other by a distance which is longer than a distance between the through hole and the connector. 8 . The electric-power control device of claim 1 , wherein the power semiconductor module includes two ground terminals including the ground terminal, wherein the first ground pattern portion includes a first high-pressure ground pattern portion provided as a ground electrode connected to one of the ground terminals, and a first low-pressure ground pattern portion provided as a ground electrode which is separated from the first high-pressure ground pattern portion and connected to an other of the ground terminals. 9 . The electric-power control device of claim 1 , wherein the substrate is integrally molded out of resin. 10 . The electric-power control device of claim 1 , wherein part of the substrate that is located opposite to the connector with respect to the through hole and also located between the power semiconductor module and the microcomputer is partially cut from an outer periphery of the substrate to an inner periphery thereof. 11 . The electric-power control device of claim 1 , wherein the microcomputer includes a nonvolatile memory and a dedicated lead wire for use in transmission of a signal for rewriting data in the nonvolatile memory. 12 . An electric motor comprising: a rotor into which a rotation shaft is inserted; a stator provided on an outer peripheral side of the rotor; and the electric-power control device of claim 1 , wherein the stator and the electric-power control device are integrally molded out of a mold resin. 13 . An air-conditioning apparatus in which a compressor, a condenser, an expansion valve and an evaporator are connected by pipes to circulate refrigerant, the air-conditioning apparatus comprising: a fan which sends air to at least one of the condenser and the evaporator; and the electric motor of claim 12 which serves as a power source for the fan. 14 . A method for manufacturing an electric motor including a rotor into which a rotation shaft is inserted and a stator which is provided on an outer peripheral side of the rotor, the method comprising: a ground pattern forming step of forming, on an annular substrate including a through hole through which the rotation shaft passes, a first ground pattern portion which is connected to a ground terminal of a power semiconductor module and a second ground pattern portion which is connected to a ground terminal of a microcomputer; and a component mounting step of mounting the power semiconductor module on a first region which is one of sides of the substrate which are divided with respect to a straight line connecting a center of the through hole to a center of a connector provided at a peripheral portion of the substrate, and also mounting the microcomputer on a second region which is an other of the substrate, in the ground pattern forming step, the first ground pattern portion being formed to extend from the power semiconductor module toward the connecter in the first region, and the second ground pattern portion being formed to extend from the microcomputer toward the connector in the second region and separately from the first ground pattern portion. 15 . The method for manufacturing an electric motor of claim 14 , wherein in the component mounting step, a magnetic-pole position detection sensor which detects a position of the rotor is further mounted, the method further comprising a measuring and writing step of measuring, after the component mounting step, a phase shift between a magnetic-pole position of the rotor and a magnetic-pole position detection signal output from the magnetic-pole position detection sensor and an overcurrent limit value, and writing the measured phase shift and overcurrent limit values to the nonvolatile memory of the microcomputer.