An object of the present invention is to provide a power conversion device capable of suppressing an increase in a current flowing through a motor even if a voltage command exceeds the amplitude of a carrier wave. In order to achieve the above object, the power conversion device controls the driving of a motor by converting a DC voltage into a voltage based on a voltage command by an operation of a switching circuit and includes: a modulated wave generator that generates a first modulated wave from the voltage command; and a control signal generator that generates a control signal for controlling the operation of the switching circuit from the first modulated wave and a carrier wave. The modulated wave generator generates a square wave based on a voltage command norm as the first modulated wave.

A power conversion device includes a first power conversion circuit portion and a second power conversion circuit portion delivering power to and from first and second motors of which shaft centers are disposed along a first direction, three first connection terminals connecting the first power conversion circuit portion and the first motor, and three second connection terminals connecting the second power conversion circuit portion and the second motor. The first power conversion circuit portion and the second power conversion circuit portion are configured such that, when seen in radial directions of the first motor and the second motor, at least a portion thereof overlaps at least any of the first motor and the second motor. Three first connection terminals are disposed along the first direction on one side in a second direction. Three second connection terminals are disposed along the first direction on the other side in the second direction.

A sawing tool includes a motor; a battery pack supplying power to the motor; and a control circuit for controlling the motor to rotate or brake. The control circuit includes a driver circuit including multiple high-side switching elements and multiple low-side switching elements; and a controller electrically connected to at least the driver circuit and outputting a control signal to control the states of the multiple high-side switching elements and the multiple low-side switching elements. The controller is configured to: in response to a brake signal, control the driver circuit to operate in an energy feedback state and adjust the duty cycle of the control signal to adjust the magnitude of the feedback current in the energy feedback state. The energy feedback state includes a brake mode and a freewheeling mode; and the feedback current generated in the freewheeling mode is fed back to the battery pack.

A brushless electric motor includes: a stator core, which includes Z tooth groups spaced apart from each other in a first circumferential direction; a rotor, which includes a magnetic ring having P poles, P being an even number; and X phase conductors, which are wound on the tooth groups to form coils, where X2, and Z=PX, wherein in the same phase conductor, the coils on two adjacent tooth groups have opposite winding directions in a second circumferential direction of the tooth groups, and are spaced apart by X1 tooth groups.