Abstract: An object is to suppress a decrease in reliability due to peeling of an insulating layer and another member of a power semiconductor device. A power semiconductor device according to the present invention includes: a power semiconductor element; a conductor portion that transmits a current to the power semiconductor element; an insulating layer in contact with a surface of the conductor portion on a side opposite to a side on which the power semiconductor element is arranged; a metallic heat dissipating portion that opposes the conductor portion while sandwiching the insulating layer; and an output terminal that is connected to the conductor layer and outputs a different signal depending on a contact state of the insulating portion, the insulating layer having an insulating portion and a conductor layer sandwiched between the conductor portion and the metallic heat dissipating portion via the insulating portion.

Abstract: Provided is a compressor in which vibration resistance against an excitation force due to drive of a linear motor is improved. A linear compressor 1 includes: a mover 101 and a stator 102 which relatively move in a first direction and a second direction that is an opposite direction to the first direction; and an inverter portion 300 which includes a printed circuit board 305 and circuit elements 302 and 304 connected to the printed circuit board 305 through connection lead lines 306 extending from the printed circuit board 305, wherein the printed circuit board 305 is installed in a direction substantially perpendicular to the first direction.

Abstract: An object is to suppress a decrease in reliability due to peeling of an insulating layer and another member of a power semiconductor device. A power semiconductor device according to the present invention includes: a power semiconductor element; a conductor portion that transmits a current to the power semiconductor element; an insulating layer in contact with a surface of the conductor portion on a side opposite to a side on which the power semiconductor element is arranged; a metallic heat dissipating portion that opposes the conductor portion while sandwiching the insulating layer; and an output terminal that is connected to the conductor layer and outputs a different signal depending on a contact state of the insulating portion, the insulating layer having an insulating portion and a conductor layer sandwiched between the conductor portion and the metallic heat dissipating portion via the insulating portion.

Abstract: Provided is a compressor in which vibration resistance against an excitation force due to drive of a linear motor is improved. A linear compressor 1 includes: a mover 101 and a stator 102 which relatively move in a first direction and a second direction that is an opposite direction to the first direction; and an inverter portion 300 which includes a printed circuit board 305 and circuit elements 302 and 304 connected to the printed circuit board 305 through connection lead lines 306 extending from the printed circuit board 305, wherein the printed circuit board 305 is installed in a direction substantially perpendicular to the first direction.

Abstract: An object of the present invention is to provide a small-sized and highly heat-dissipative reactor and a DC-DC converter using the reactor. A reactor according to the present invention includes a plate bus bar, a core, and a heat sink. The core includes a middle leg portion. The heat sink cools the plate bus bar. The plate bus bar is formed such that a winding axis of a winding including the plate bus bar passes through the middle leg portion. A main surface of the plate bus bar is disposed in parallel with a direction of the winding axis and thermally connected to the heat sink via an insulating layer.

Abstract: A power conversion device includes: a first low voltage side circuit and a first high voltage side circuit which are connected via a first transformer; and a second low voltage side circuit and a second high voltage side circuit which are connected via a second transformer, wherein switching timings of the first high voltage side circuit and the second high voltage side circuit are controlled such that a current difference of an input current to the first low voltage side circuit and an input current to the second low voltage side circuit during a step-up operation becomes smaller than a predetermined value. A driver circuit to output a drive signal of a switching element may be included in at least one of the first low voltage side circuit and the second low voltage side circuit.

Abstract: To suppress a temperature increase of a transformer. A transformer includes a core, a primary winding, and a secondary winding. The core includes a primary core and a secondary core disposed on a side of the primary core. The primary winding includes a first primary winding wound around the primary core and the second primary winding wound around the secondary core and electrically connected in series to the first primary winding. The first primary winding is disposed such that a direction of a magnetic flux on an inner peripheral side of the first primary winding induced by the first primary winding is opposite to a direction of the magnetic flux on the inner peripheral side of the second primary winding induced by the second primary winding. The secondary winding is wound such that a winding axial line of the first primary winding and a winding axial line of the second primary winding are formed on an inner peripheral side of the secondary winding.

Abstract: The present invention aims to provide a power converter, which includes a plurality of switching power supply devices connected in parallel, with a circuit configuration that enables reduction of cost and a size of the power converter. The present invention relates to a power converter including at least a first switching power supply device and a second switching power supply device connected in parallel. A part of high-voltage-compatible switching elements is commonly used between the first switching power supply device and the second switching power supply device, and a drive gate signal of one of the high-voltage-compatible switching elements of the first switching power supply device and the second switching power supply device and a phase difference of a drive gate signal of the commonly used switching power supply device are set to be equal when a load current is a first current value or lower.

Abstract: Provided is a power conversion device which suppresses a current unbalance of a plurality of secondary circuit modules provided in parallel and is manufactured in a compact size and at a low cost. The power conversion device of the invention is a DC-DC converter which boosts down and outputs an input voltage, and includes an input circuit which includes a switching element and output circuit modules which include a transformer and a rectifier element. A plurality of the output circuit modules are provided. The plurality of output circuit modules are electrically connected to the input circuit.

Abstract: An adverse effect on a smoothing capacitor device caused by heat is suppressed. A flow path forming body 240 provided with protruding portions 411, 412 for attaching a capacitor board, a smoothing inductor device 130 mounted on the flow path forming body 240, and a capacitor board 170A on which a smoothing capacitor device 170 is implemented are provided, and the capacitor board 170A is fixed to the protruding portions 411, 412 for attaching the capacitor board, in such a manner that the smoothing capacitor device 170 is away from the flow path forming body 240.

Abstract: Provided is a power conversion device which suppresses a current unbalance of a plurality of secondary circuit modules provided in parallel and is manufactured in a compact size and at a low cost. The power conversion device of the invention is a DC-DC converter which boosts down and outputs an input voltage, and includes an input circuit which includes a switching element and output circuit modules which include a transformer and a rectifier element. A plurality of the output circuit modules are provided. The plurality of output circuit modules are electrically connected to the input circuit.

Abstract: An object of the present invention is to provide a power conversion device which includes a plurality of switching power supply devices connected in parallel and has circuit and control configurations capable of reducing a cost and a size of the power conversion device. The power conversion device according to the present invention includes: a first low voltage side circuit and a first high voltage side circuit which are connected via a first transformer; and a second low voltage side circuit and a second high voltage side circuit which are connected via a second transformer, wherein switching timings of the first high voltage side circuit and the second high voltage side circuit are controlled such that a current difference of an input current to the first low voltage side circuit and an input current to the second low voltage side circuit during a step-up operation becomes smaller than a predetermined value.

Abstract: If an input voltage of a DC/DC converter is lower than a first voltage value that is set in advance, a converter controller maintains an output voltage of the DC/DC converter within a first voltage range that is set in advance by changing an operation frequency of switching of the DC/DC converter in compliance with the input voltage as a first voltage maintaining control. If the input voltage is higher than a second voltage value that is higher than the first voltage value, the converter controller maintains the output voltage within a second voltage range that is higher than the first voltage range by changing the operation frequency in compliance with the input voltage as a second voltage maintaining control.

Abstract: The present invention aims to provide a power converter, which includes a plurality of switching power supply devices connected in parallel, with a circuit configuration that enables reduction of cost and a size of the power converter. The present invention relates to a power converter including at least a first switching power supply device and a second switching power supply device connected in parallel. A part of high-voltage-compatible switching elements is commonly used between the first switching power supply device and the second switching power supply device, and a drive gate signal of one of the high-voltage-compatible switching elements of the first switching power supply device and the second switching power supply device and a phase difference of a drive gate signal of the commonly used switching power supply device are set to be equal when a load current is a first current value or lower.

Abstract: Reduction in size and weight of transformer for grid tie applications is demanded and can be achieved by applying SST to the transformer. However, SST application to PCS for sunlight requires the following: handle a wide variation range of the voltage of solar power generation; reduce switching losses of power devices, DC/DC converter and inverter, in the power circuit to implement high frequency for SST application; increase voltage to the grid voltage; and reduce the dimensions of the high current path prior to step-up. Thus, LLC resonant converter configuration is applied with an inverter placed in the output, and series connected configuration is applied to the inverter. The LLC resonant converter is subject to constant frequency regulation with large output, step-up control with low output, and step-down control with the upper limit voltage according to MPPT voltage from sunlight, in order to achieve drive loss reduction and voltage range handling.

Abstract: An object of the present invention is to provide a small-sized and highly heat-dissipative reactor and a DC-DC converter using the reactor. A reactor according to the present invention includes a plate bus bar, a core, and a heat sink. The core includes a middle leg portion. The heat sink cools the plate bus bar. The plate bus bar is formed such that a winding axis of a winding including the plate bus bar passes through the middle leg portion. A main surface of the plate bus bar is disposed in parallel with a direction of the winding axis and thermally connected to the heat sink via an insulating layer.

Abstract: In a DC-DC converter, the cooling of switching elements has been performed only by means of a cooling plate; therefore, there is a problem in that, to effectively radiate heats generated by power MOSFETs that have large heating values and that are arranged parallel, it becomes necessary to reduce thermal resistances and complicate the cooling route of a water-cooling device. Plural switching elements for controlling currents flowing through inductor elements, which are used for voltage conversion of a DC-DC converter, are fixed to a metal case via a heat conductive insulating material and via a metal radiator having a better heat conduction characteristic than the metal case. Because there occur no large mixing phenomena of heat currents among neighboring switching elements, and there are only little heat interferences between the neighboring switching elements, the thermal diffusion characteristic is improved, and the cooling efficiency for the switching elements can be increased.

Abstract: An adverse effect on a smoothing capacitor device caused by heat is suppressed. A flow path forming body 240 provided with protruding portions 411, 412 for attaching a capacitor board, a smoothing inductor device 130 mounted on the flow path forming body 240, and a capacitor board 170A on which a smoothing capacitor device 170 is implemented are provided, and the capacitor board 170A is fixed to the protruding portions 411, 412 for attaching the capacitor board, in such a manner that the smoothing capacitor device 170 is away from the flow path forming body 240.

Abstract: To suppress a temperature increase of a transformer. A transformer includes a core, a primary winding, and a secondary winding. The core includes a primary core and a secondary core disposed on a side of the primary core. The primary winding includes a first primary winding wound around the primary core and the second primary winding wound around the secondary core and electrically connected in series to the first primary winding. The first primary winding is disposed such that a direction of a magnetic flux on an inner peripheral side of the first primary winding induced by the first primary winding is opposite to a direction of the magnetic flux on the inner peripheral side of the second primary winding induced, by the second primary winding. The secondary winding is wound such that a winding axial line of the first primary winding and a winding axial line of the second primary winding are formed on an inner peripheral side of the secondary winding.

Abstract: Reduction in size and weight of transformer for grid tie applications is demanded and can be achieved by applying SST to the transformer. However, SST application to PCS for sunlight requires the following: handle a wide variation range of the voltage of solar power generation; reduce switching losses of power devices, DC/DC converter and inverter, in the power circuit to implement high frequency for SST application; increase voltage to the grid voltage; and reduce the dimensions of the high current path prior to step-up. Thus, LLC resonant converter configuration is applied with an inverter placed in the output, and series connected configuration is applied to the inverter. The LLC resonant converter is subject to constant frequency regulation with large output, step-up control with low output, and step-down control with the upper limit voltage according to MPPT voltage from sunlight, in order to achieve drive loss reduction and voltage range handling.