Abstract: An electronic equipment is provided with a semiconductor device including an electrode joined to an electric conductor via a joint layer, a calculator and a controller. The semiconductor device is configured to pass current bidirectionally. The calculator is configured to calculate an imbalance EM progression index. The imbalance EM progression index is a difference between a forward current EM progression index and a reverse current EM progression index. The controller is configured to: adopt a condition to accelerate an increase rate of the reverse current EM progression index in at least a part of an excessive forward current EM period; and adopt a condition to accelerate an increase rate of the forward current EM progression index in at least a part of an excessive reverse current EM period.

Abstract: A drum washing machine, including: a driving part, capable of operating in a uniaxial driving form and a biaxial driving form; a heater configured to heat water stored in the outer drum for washing; and a control part which at least performs washing operation of a first washing mode and a second washing mode. In a washing process of the first washing mode, the control part enables the driving part to operate in the uniaxial driving form and also enables the heater to operate. Further, in a washing process of the second washing mode, the control part enables the driving part to operate in the biaxial driving form and also enables the heater to operate in such a manner that heat applied to the water is reduced compared with the first washing mode.

Abstract: A receiving part (2) has a substantially rectangular shape with short sides and long sides, and its short-side inner surface (15) is provided with a central latch claw (32) in a substantially central region thereof with respect to a short side direction, with side elastic latch portions (33) provided on both sides of the central latch claw (32) with respect to the short side direction. Each of the side elastic latch portions (33) includes a receiving-part rib (34), an elastic piece (35), and a side elastic latch claw (38). The receiving-part rib (34) protrudes from the short-side inner surface (15) and extends in the insertion direction. The elastic piece (35) is arranged between the receiving-part rib (34) and a long-side inner surface ((17) or (18)), and elastically deformable. The side elastic latch claw (38) is formed on the elastic piece (35).

Abstract: An analyzing method of a spot welded portion, includes: acquiring bar elements as the spot welded portion; extracting other bar elements existing at a periphery of a target bar element which is targeted among the acquired bar elements; determining whether or not there is a bar element which shares the same end point with the target bar element among the extracted bar elements; determining that the target bar element and the bar element which shares the same end point with the target bar element are a three-layer spot welded portion when it is determined that there is the bar element which shares the same end point with the target bar element; and determining whether or not there is a bar element whose distance between elements with the target bar element is within a predetermined distance among the extracted bar elements when it is determined that there is not the bar element which shares the same end point with the target bar element, and determining that the target bar element and the extracted bar element

Abstract: A drum washing machine, which decelerates rotation of a driving motor through a planetary gear mechanism and transfers the rotation to the drum, so that the drum and a rotating body with a projection rotate at different rotating speeds. The planetary gear mechanism includes a sun gear, an internal gear, a plurality of planetary gears, planetary gear carrier. The planetary gear carrier has a rear planetary carrier and a front planetary carrier, through which the planetary gears are clamped from both sides thereof, supporting shafts erected between the front and the rear planetary carrier, the planetary gears are rotatably provided on the supporting shafts. Base ends of the supporting shafts are fixed on the rear planetary carrier before the planetary gears being provided on the supporting shafts The front planetary carrier is fixed at front ends of the supporting shafts provided with the planetary gears.

Abstract: A receiving part (2) has a substantially rectangular shape with short sides and long sides, and its short-side inner surface (15) is provided with a central latch claw (32) in a substantially central region thereof with respect to a short side direction, with side elastic latch portions (33) provided on both sides of the central latch claw (32) with respect to the short side direction. Each of the side elastic latch portions (33) includes a receiving-part rib (34), an elastic piece (35), and a side elastic latch claw (38). The receiving-part rib (34) protrudes from the short-side inner surface (15) and extends in the insertion direction. The elastic piece (35) is arranged between the receiving-part rib (34) and a long-side inner surface ((17) or (18)), and elastically deformable. The side elastic latch claw (38) is formed on the elastic piece (35).

Abstract: Two or more pads and are connected to a gate region, so that a pad for applying a gate voltage can be selected. In the case where, for example, the peripheral region is likely to overheat, a turn-on voltage is applied to the first pad to turn on the peripheral region later than the central region, and a turn-off voltage is applied to the second pad to turn off the peripheral region earlier than the central region. The problem that the peripheral region is likely to overheat can be addressed. In the case where the flow of an excess current raises the temperature, the turn-off voltage is applied to the second pad. The problem that the temperature is likely to rise in the peripheral region when an excess current flows can be addressed.

Abstract: An electronic equipment is provided with a semiconductor device including an electrode joined to an electric conductor via a joint layer, a calculator and a controller. The semiconductor device is configured to pass current bidirectionally. The calculator is configured to calculate an imbalance EM progression index. The imbalance EM progression index is a difference between a forward current EM progression index and a reverse current EM progression index. The controller is configured to: adopt a condition to accelerate an increase rate of the reverse current EM progression index in at least a part of an excessive forward current EM period; and adopt a condition to accelerate an increase rate of the forward current EM progression index in at least a part of an excessive reverse current EM period.

Abstract: A hollow columnar shock absorbing member (1) has an axis (O), a plurality of rectangular walls (1a, 1b, 1c, 1d) extending parallel to axis (O), and a polygonal cross-section perpendicular to axis (O), wherein the shock absorbing member extends in the direction of axis (O) and absorbs externally-applied impact energy while buckling in the direction of axis (O). The shock absorbing member has at least one bead (2a, 2b, 2c, 2d) formed on at least one wall (1a, 1b, 1c, 1d) among the plurality of walls (1a, 1b, 1c, 1d), the at least one bead (2a, 2b, 2c, 2d) providing the origin of the buckling. The at least one bead (2a, 2b, 2c, 2d) is positioned so as to be deviated towards one edge of a wall (1a, 1b, 1c, 1d) on which the at least one bead (2a, 2b, 2c, 2d) is formed, the edge extending parallel to axis (O).

Abstract: A high-strength steel sheet includes, by mass %, C: 0.03% to 0.30%, Si: 0.08% to 2.1%, Mn: 0.5% to 4.0%, P: 0.05% or less, S: 0.0001% to 0.1%, N: 0.01% or less, acid-soluble Al: more than 0.004% and less than or equal to 2.0%, acid-soluble Ti: 0.0001% to 0.20%, at least one selected from Ce and La: 0.001% to 0.04% in total, and a balance of iron and inevitable impurities, in which [Ce], [La], [acid-soluble Al], and [S] satisfy 0.02?([Ce]+[La])/[acid-soluble Al]<0.25, and 0.4?([Ce]+[La])/[S]?50 in a case in which the mass percentages of Ce, La, acid-soluble Al, and S are defined to be [Ce], [La], [acid-soluble Al], and [S], respectively, and a microstructure includes 1% to 50% of martensite in terms of an area ratio.

Abstract: A hollow columnar shock absorbing member (1) has an axis (O), a plurality of rectangular walls (1a, 1b, 1c, 1d) extending parallel to axis (O), and a polygonal cross-section perpendicular to axis (O), the shock absorbing member extending in the direction of axis (O) and absorbing externally-applied impact energy while buckling in the direction of axis (O). Shock absorbing member (1) is provided with at least two flanges (2a, 2b, 2c, 2d) protruding from at least two edges (1e, 1f, 1g, 1h) formed by at least two sets of neighboring walls among a plurality of walls, and the at least two flanges are arranged so that the directions of protrusion of the flanges from the edges are directed to the same direction with respect to a circumferential direction.

Abstract: A cooling type switching element module includes an outer conductor pipe, an inner conductor pipe that transmits electric power in conjunction with the outer conductor pipe, and first and second switching elements. The first switching elements are provided on outer surfaces of the outer conductor pipe, and the second switching elements are provided on outer surfaces of a projecting portion of the inner conductor pipe. A coolant flows within the inner conductor pipe, and outside the outer conductor pipe. The first and second switching elements are cooled from both sides by the coolant flowing within the inner conductor pipe, and by the coolant flowing outside the outer conductor pipe. By employing the above-described structure, it is possible to provide a switching element module having a cooling function, in which improved cooling performance, improved electrical performance, and downsizing are achieved.

Abstract: An analyzing method of a spot welded portion, includes: acquiring bar elements as the spot welded portion; extracting other bar elements existing at a periphery of a target bar element which is targeted among the acquired bar elements; determining whether or not there is a bar element which shares the same end point with the target bar element among the extracted bar elements; determining that the target bar element and the bar element which shares the same end point with the target bar element are a three-layer spot welded portion when it is determined that there is the bar element which shares the same end point with the target bar element; and determining whether or not there is a bar element whose distance between elements with the target bar element is within a predetermined distance among the extracted bar elements when it is determined that there is not the bar element which shares the same end point with the target bar element, and determining that the target bar element and the extracted bar element

Abstract: The deformation analysis device includes: a storage unit (12) which stores analysis data of a material; a state variable calculating unit (152) which calculates stresses and other state variables of respective elements of the material at each point in time of deformation of the material, based on the analysis data; a fracture determining unit (153) which, based on the calculated state variables, determines whether or not a fracture has occurred in each of the elements of the material, based on a fracture limit stress curve which is found in advance for the material; and a stress correcting unit (154) which, regarding an element in which it is determined that the fracture has occurred, out of the elements of the material, reduces ? by the following expression ?=(1?D)?? where ? is a stress with a rigidity decrease taken into consideration, D is a damage variable (note that 0?D?1) in continuum damage mechanics, and ?? is a stress with the rigidity decrease not taken into consideration, to thereby decrease rigidi

Abstract: Two or more pads and are connected to a gate region, so that a pad for applying a gate voltage can be selected. In the case where, for example, the peripheral region is likely to overheat, a turn-on voltage is applied to the first pad to turn on the peripheral region later than the central region, and a turn-off voltage is applied to the second pad to turn off the peripheral region earlier than the central region. The problem that the peripheral region is likely to overheat can be addressed. In the case where the flow of an excess current raises the temperature, the turn-off voltage is applied to the second pad. The problem that the temperature is likely to rise in the peripheral region when an excess current flows can be addressed.

Abstract: A performance evaluation method of a vehicle member includes a calculation process for performing an analysis using a partial structure CAE model modeling a module where a member of a vehicle to be evaluated and a collision test device for conducting a collision test on the member are combined, and obtaining a value of a collision performance evaluation parameter in the partial structure CAE model; a calculation process for determining a boundary condition of the partial structure CAE model; a calculation process for determining a test condition of a member collision test device based on the boundary condition of the partial structure CAE model; and a test process for conducting a collision test using a physical member collision test device and a physical member, based on the set condition of the member collision test device.

Abstract: A semiconductor device includes a first electrode, a second electrode, and an endothermic layer. The first electrode, the second electrode and the endothermic layer are formed on a semiconductor substrate. The first electrode is electrically conductive with an element formed inside of the semiconductor substrate. The endothermic layer is in contact with the first electrode and has electric conductivity. The second electrode is in contact with at least one of the first electrode and the endothermic layer and soldered to a metal electric conductor. Herein, at least one of a work function and contact resistivity of the first electrode is smaller than that of the endothermic layer. A heat of melting of the endothermic layer is larger than that of the first electrode. Solder joinability of the second electrode is higher than that of the endothermic layer.

Abstract: A PCU drives a motor generator using electric power from a power storage device. The PCU includes a power conversion device, a capacitor and a control unit. When detecting a crash, the control unit drives the power conversion device and discharges charges remaining in the capacitor. Each of a plurality of reverse conducting-type semiconductor elements included in the power conversion device is integrally formed of a first semiconductor element operating as a switching element and a second semiconductor element operating as a free wheeling diode. In response to detection of the crash of a vehicle, the control unit changes a voltage applied to a gate terminal of the first semiconductor element and increases an electric power loss during a current-circulating operation by the second semiconductor element. As a result, the remaining charges stored in the capacitor in the drive apparatus is discharged as soon as possible.

Abstract: A metallic hollow columnar member with a polygonal cross-section having at least five vertices and sides extending between the vertices, is disclosed. The polygonal cross-section is divided by two vertices (A, B) with small inside angles into two perimeter segments with a perimeter comprising one or more sides, and at least one of the two perimeter segments contains at least four sides. The respective inside angles of at least three vertices (V(i)) included in the perimeter segment which includes the at least four sides are equal to or less than 180°, the distance (SS(i)) between each of the at least three vertices (V(i)) and a straight line (L) connecting the two vertices (A, B) is shorter than ½ of the distance between the two vertices (A, B), and the inside angle of the vertex (C) with the smallest inside angle among the at least three vertices (V(i)) is larger than the inside angles of the two vertices (A, B).

Abstract: A cooling type switching element module includes an outer conductor pipe, an inner conductor pipe that transmits electric power in conjunction with the outer conductor pipe, and first and second switching elements. The first switching elements are provided on outer surfaces of the outer conductor pipe, and the second switching elements are provided on outer surfaces of a projecting portion of the inner conductor pipe. A coolant flows within the inner conductor pipe, and outside the outer conductor pipe. The first and second switching elements are cooled from both sides by the coolant flowing within the inner conductor pipe, and by the coolant flowing outside the outer conductor pipe. By employing the above-described structure, it is possible to provide a switching element module having a cooling function, in which improved cooling performance, improved electrical performance, and downsizing are achieved.