Abstract: A non-contact power transmission device equipped with a ground-side device and a vehicle-side device. The ground-side device has a primary-side coil to which alternating-current power is input. The vehicle-side device includes a secondary-side coil, a battery, a secondary-side matching device, and a charging device. The secondary-side coil receives alternating-current power from the primary-side coil in a non-contact manner. The secondary-side matching device is provided between the secondary-side coil and the battery, and has a predetermined fixed inductance and fixed capacitance. The charging device has a switching element that performs a switching operation with a prescribed cycle. The charging device adjusts the duty ratio of the switching operation in accordance with the impedance of a load.

Abstract: A contactless power transmission device includes a switching unit that switches a power transmission line so that a first power is transmitted through the first line when an AC power supply outputs a first AC power and so that a second power is transmitted through a second line when the AC power supply outputs a second AC power. An impedance conversion unit is arranged on the second line that converts an impedance from an output of the AC power supply to a variable load when the second power is transmitted through the second line to approach an impedance from the output of the AC power supply to the variable load when the first power is transmitted through the first line.

Abstract: A vehicle front section structure comprising a side rail extending along a vehicle front-rear direction at a vehicle width direction outside of a vehicle front section, the side rail including a bent portion at the vehicle rear side of a front tire, and the bent portion bending toward the vehicle width direction outside on progression from the vehicle front toward the vehicle rear; and a projection projecting out from the bent portion toward the vehicle width direction outside, and having an angled face angled toward the vehicle width direction outside on progression from the vehicle front toward the vehicle rear at a face of the projection facing the front tire.

Abstract: An object is to suppress deterioration of a high-voltage side battery regardless of the magnitude of a load current. Provided is a control device of a DC-DC converter that is constituted by a primary side circuit that is electrically connected between an input side and a transformer, and a secondary side circuit that is electrically connected between an output side and the transformer. The control device includes a command generating unit 325 that sets an output current limiting value to a predetermined value on the basis of a detected input voltage, a duty generating unit 330 that calculates a duty configured to turn ON/OFF a switching element on the basis of the output current limiting value and a detected output current, and a switching signal generating unit 335 that generates a switching signal on the basis of the duty. The duty generating unit 330 generates the duty so that an output current is limited to the output current limiting value or less.

Abstract: An object is to suppress deterioration of a high-voltage side battery regardless of the magnitude of a load current. Provided is a control device of a DC-DC converter that is constituted by a primary side circuit that is electrically connected between an input side and a transformer, and a secondary side circuit that is electrically connected between an output side and the transformer. The control device includes a command generating unit 325 that sets an output current limiting value to a predetermined value on the basis of a detected input voltage, a duty generating unit 330 that calculates a duty configured to turn ON/OFF a switching element on the basis of the output current limiting value and a detected output current, and a switching signal generating unit 335 that generates a switching signal on the basis of the duty. The duty generating unit 330 generates the duty so that an output current is limited to the output current limiting value or less.

Abstract: A receiving device includes: a secondary coil capable of wirelessly receiving alternating current power; a load having an impedance that varies in accordance with a value of input power; a variable impedance conversion unit located between the secondary coil and the load; a plurality of adjusting resistors located at an output side of the variable impedance conversion unit, wherein the adjusting resistors respectively have resistances that are fixed regardless of the value of the input power and differ from each other; and a switch that switches a subject supplied with power output from the variable impedance conversion unit to one of the load and the adjusting resistors. When the impedance of the variable impedance conversion unit is variably controlled, the subject supplied with the power output from the variable impedance conversion unit is switched to one of the adjusting resistors.

Abstract: A vehicle front section structure comprising a side rail extending along a vehicle front-rear direction at a vehicle width direction outside of a vehicle front section, the side rail including a bent portion at the vehicle rear side of a front tire, and the bent portion bending toward the vehicle width direction outside on progression from the vehicle front toward the vehicle rear; and a projection projecting out from the bent portion toward the vehicle width direction outside, and having an angled face angled toward the vehicle width direction outside on progression from the vehicle front toward the vehicle rear at a face of the projection facing the front tire.

Abstract: A power supply device is capable of transferring AC power in a noncontact manner to a secondary coil of a power receiving device. The power supply device includes an AC power supply that outputs the AC power. The AC power supply includes a DC/AC conversion unit that converts DC power to the AC power, which has a predetermined frequency. A primary coil receives the AC power. A control unit controls the AC power output from the AC power supply. The control unit is configured to suspend the output of the AC power from the AC power supply or decrease the AC power based on input power, input current value, output power, or output current value of the DC/AC conversion unit and a power factor or a current difference of the input current value and the output current value.

Abstract: A power receiving device receives alternating current power in a wireless manner from a power supply device including a primary coil that receives the alternating current power. The power receiving device includes a secondary coil, a variable load, a first impedance conversion unit, a second impedance conversion unit, a fixed load, and a switch. The switch switches an output destination, to which the alternating current power received by the secondary coil is output from the first impedance conversion unit, to the fixed load or to the second impedance conversion unit and the variable load.

Abstract: A power-receiving device includes a secondary coil, which wirelessly receives AC power from a power-supply device having a primary coil, a variable load, in which an impedance changes in accordance with the power value of the input power, a PFC circuit having a first switching element, and a DC/DC converter having a second switching element. The PFC circuit rectifies the AC power received by the secondary coil and improves the power factor by adjusting the duty cycle in switching operation of the first switching element in accordance with the impedance fluctuation of the variable load. The DC/DC converter is configured to convert the voltage of the DC power to a different voltage and output the converted voltage to the variable load, and to adjust the duty cycle in switching operation of the second switching element in accordance with the impedance fluctuation of the variable load.

Abstract: A power-receiving device includes a secondary-side coil which can receive a first alternating current power without contact from a power-sending device having a primary side coil into which first alternating current power is input. The power-receiving device comprises a first power transmission path, a second power transmission path, a common path positioned in common with the first and second power transmission paths, and a voltage regulator arranged on the common path. The voltage regulator rectifies the first alternating current power received by the secondary coil or the second alternating current power from a connecting portion, converts the rectified power to a predetermined specific voltage value, and outputs the power.

Abstract: A non-contact power transmission device equipped with a ground-side device and a vehicle-side device. The ground-side device has a primary-side coil to which alternating-current power is input. The vehicle-side device includes a secondary-side coil, a battery, a secondary-side matching device, and a charging device. The secondary-side coil receives alternating-current power from the primary-side coil in a non-contact manner. The secondary-side matching device is provided between the secondary-side coil and the battery, and has a predetermined fixed inductance and fixed capacitance. The charging device has a switching element that performs a switching operation with a prescribed cycle. The charging device adjusts the duty ratio of the switching operation in accordance with the impedance of a load.

Abstract: A contactless power transmission device includes a switching unit that switches a power transmission line so that a first power is transmitted through the first line when an AC power supply outputs a first AC power and so that a second power is transmitted through a second line when the AC power supply outputs a second AC power. An impedance conversion unit is arranged on the second line that converts an impedance from an output of the AC power supply to a variable load when the second power is transmitted through the second line to approach an impedance from the output of the AC power supply to the variable load when the first power is transmitted through the first line.

Abstract: A greasing through hole is perforated through one outer link plate, and greasing device is attached to the through hole. Degreasing through-holes are perforated through an outer link plate or an inner link plate on the side distant from the outer link plate with a bearing section A between the link plates, and degreasing device 22 is attached to those through-holes. Lubricant injected from the greasing device is supplied to the bearing section A through a gap c between the sealing device and the outer link plate, and used lubricant within the bearing section A is discharged out of the degreasing device through another gap c.

Abstract: A greasing through hole 201 is perforated through one outer link plate 31 and greasing means 21 is attached to the through hole. Degreasing through holes 202 and 203 are perforated through an outer link plate 32 or an inner link plate 22 on the side distant from the outer link plate with a bearing section A between and degreasing means 22 are attached to those through holes. Lubricant injected from the greasing means 21 is supplied to the bearing section A through a gap c between the sealing means 6 and the outer link plate 3 and used lubricant within the bearing section A is discharged out of the degreasing means 22 through another gap c.

Abstract: In blanking holes in plates that comprise a chain, in order to improve the fatigue strength of the chain, a press-punched plate prepared hole, trumpet-shaped, is shaved and made into a straight hole, both ends of the straight hole are chamfered, and further, a multi-step burnishing punch composed of a plurality of annular convex portions at predetermined intervals is pressed into the straight hole, improving the dimensional accuracy of the hole and the smoothness of the hole wall and producing compressive residual stress in the hole wall.

Abstract: A right outer link plate of a bicycle chain, when viewed from the rear and top, has a projection swelling outwardly on a center edge thereof to lead a tooth of a sprocket into an outwardly spread recess formed by the projection. A left outer link plate of the bicycle chain, when viewed from the rear end top, has a flat face outside and an outwardly tapered face along a central inside portion to lead a tooth of the sprocket into a recess formed by the tapered face. In a front multi - stage sprocket, unit the projection of the right outer plate catches onto a tooth of the large sprocket and the tooth slips into the outwardly spread recess formed by the projection, assuring that the chain shifts from the small sprocket to the large sprocket easily. Although the center edge on the right outer link plate swells outwardly, the front multi - stage sprocket unit has a comparatively wide space between sprockets, and the projection does not interfere with the large sprocket and disturb speed changes.

Abstract: A chain joint for a power transmission chain comprises a joint pin and a projecting bush having brims swelling outwardly both its ends with at least one a slit extending longitudinally through the bush. The projecting bush is inserted into a pin hole and a bush hole of the chain, and the joint pin is pressed in an inner hole of the projecting bush. Then, the projecting bush is spread outwardly due to the slit and fits in the pin hole perfectly. Furthermore, the brims engage with the outer link plates on their outsides to prevent the projecting bush from coming off.