Abstract: A rolling bearing device for a wheel includes: a hub wheel including a hub spindle to be assembled with a rolling bearing, a flange formed on the hub spindle, and a bolt hole formed through the flange; a hub bolt to be press-fitted in the bolt hole, in which hub bolt includes a shank formed with a serrated shank portion to press-fitted to bite the bolt hole, an intermediate shank portion and a threaded portion in this order; and an annular ridge formed on an inner circumference of an opening on a press-fit exit side of the bolt hole. The annular ridge have a diameter smaller than that of the bolt hole and comes into contact or close to the intermediate shank portion to clog the bolt hole.

Abstract: A system for charging a power tool battery includes a charging device capable of charging a battery, a memory device capable of storing data of a plurality of sound patterns, a selecting device capable of selecting a sound pattern data from the plurality of sound patterns, and a sound generating device capable of generating a sound based on the selected sound pattern data when the charging operation of the battery by the charging device has been completed.

Abstract: Battery pack may include rechargeable battery cells Battery charger may include power source circuit. Power source circuit may be connected with an external power source and battery cells. The external power source may supply power to the power source circuit and then, the power source circuit may supply charging current to battery cells. Battery charger may also include voltage detector for detecting the voltage input from the external power source to power source circuit. Battery charger may further include processor for controlling power source circuit. Processor may determine the amount of charging current supplied to battery cells based upon the external power source voltage detected by the voltage detector.

Abstract: Battery pack 10 may include rechargeable battery 12 and remaining capacity indicating circuit 14 for indicating the remaining capacity of the battery 12. Remaining capacity indicating circuit 14 may be coupled to the battery 12 via first switch SW1. When first switch SW1 is turned ON, a current flows from battery 12 to remaining capacity indicating circuit 14. When the first switch SW1 is turned OFF, the current flowing from battery 12 to remaining capacity indicating circuit 14 is turned OFF. The first switch SW1 may be coupled to first voltage detecting circuit (R2, R3) for detecting the voltage of battery 12. When the voltage that is being detected of battery 12 falls below a first predetermined value, first switch SW1 is turned off. Battery pack 10 may further include cut-off circuit (SW2, R4, R5) that cuts off the flow of current from battery 12 to first voltage detecting circuit (R2, R3) when first switch SW1 has been turned OFF.

Abstract: Battery pack (10) may include rechargeable battery cells (12). Battery charger (20) may include power source circuit (100). Power source circuit (100) may be connected with an external power source and battery cells (12). The external power source may supply power to the power source circuit and then, the power source circuit may supply charging current to battery cells (12). Battery charger (20) may also include voltage detector (32, 33) for detecting the voltage input from the external power source to power source circuit (100). Battery charger (10) may further include processor (40) for controlling power source circuit (32). Processor (40) may determine the amount of charging current supplied to battery cells (12) based upon the external power source voltage detected by the voltage detector (32, 33).

Abstract: Battery pack 10 may include rechargeable battery 12 and remaining capacity indicating circuit 14 for indicating the remaining capacity of the battery 12. Remaining capacity indicating circuit 14 may be coupled to the battery 12 via first switch SW1. When first switch SW1 is turned ON, a current flows from battery 12 to remaining capacity indicating circuit 14. When the first switch SW1 is turned OFF, the current flowing from battery 12 to remaining capacity indicating circuit 14 is turned OFF. The first switch SW1 may be coupled to first voltage detecting circuit (R2, R3) for detecting the voltage of battery 12. When the voltage that is being detected of battery 12 falls below a first predetermined value, first switch SW1 is turned off. Battery pack 10 may further include cut-off circuit (SW2, R4, R5) that cuts off the flow of current from battery 12 to first voltage detecting circuit (R2, R3) when first switch SW1 has been turned OFF.

Abstract: Battery pack (10) may include rechargeable battery cells (12). Battery charger (20) may include power source circuit (100). Power source circuit (100) may be connected with an external power source and battery cells (12). The external power source may supply power to the power source circuit and then, the power source circuit may supply charging current to battery cells (12). Battery charger (20) may also include voltage detector (32, 33) for detecting the voltage input from the external power source to power source circuit (100). Battery charger (10) may further include processor (40) for controlling power source circuit (32). Processor (40) may determine the amount of charging current supplied to battery cells (12) based upon the external power source voltage detected by the voltage detector (32, 33).

Abstract: A battery charging system is disclosed for charging two different types of battery packs, a known three terminal type including batteries and a thermostat switch, and a newer four terminal type further including a thermistor for sensing battery temperature. A charging control circuit stops charging current to the battery pack when a contact of the thermostat switch is open or when the thermistor detects a temperature above a predetermined temperature. If either the thermostat switch or the thermistor fail to properly operate, charging current to the battery pack is stopped securely to avoid damaging batteries.

Abstract: A battery charger includes a microcomputer operable to receive an input value corresponding to a value of charging current. A thyristor has the gate connected to an output port of the microcomputer. The microcomputer operable to adjust the firing angle of the thyristor for controlling the value of the charging current through a phase control of the charging current in response to the input value. A capacitor has a first electrode connected to the gate of the thyristor. A transistor has the collector connected to a second electrode of the capacitor, the base connected to the output port of the microcomputer, and the emitter connected to a power source voltage for the microcomputer.

Abstract: A battery charger includes a battery voltage detecting circuit for detecting a voltage of a battery during a charging operation. The battery voltage detecting circuit includes a pair of a first and a second voltage-dividing resistor. A transistor is interposed between the first and second voltage-dividing resistors. A predetermined voltage is applied to the base of the transistor, so that the battery voltage is detected based on the voltage divided by the first and second voltage-dividing resistors.