Abstract: A starter driving semiconductor switch apparatus energizes and de-energizes a starter according to a command from an outside. A series circuit to which semiconductor switches are connected in series is provided between a battery serving as a power supply and the starter. The starter is energized by bringing all the semiconductor switches into conduction. A voltage or a current at a predetermined point in the series circuit is monitored to make a self-diagnosis on whether the starter is allowed to start and whether there is a failure in the semiconductor switches according to a monitor output. The starter driving semiconductor switch apparatus is thus expected to have a longer useful life by energizing the starter not by using mechanical contacts but by using semiconductor switches.

Abstract: A vehicle component mounting structure is provided with a vehicle body, a battery, a charger, a high-power electrical component other than the charger. The battery is mounted on the vehicle body. The charger is mounted on the vehicle body and converts a lower-voltage electric power supplied thereto from an external source into a higher-voltage electric power that is supplied to the battery. The high-power electrical component is mounted on the vehicle body with high voltage being supplied to the high-power electrical component. The charger and the high-power electrical component are arranged on longitudinally opposite sides of the battery with respect to a longitudinal direction of the vehicle body.

Abstract: When predetermined conditions in a vehicle are met, the control means of the disclosed vehicle control device prohibits control of the state of power-source supply to vehicle-mounted equipment or the operating state of a drive source resulting from a pressing operation of a push switch. When it is detected that an abnormal state has arisen in the vehicle, the control means allows control by the pressing operation of the push switch even if the aforementioned predetermined conditions are met.

Abstract: This invention is a way to disable a electrical circuit in a mobile vehicle or equipment. This invention works in conjunction with our previous Patent, EMERGENCY SHUTOFF SYSTEM FOR POWER MACHINERY, WIRELESS MONITORING SYSTEMS, AND EMERGENCY SHUTOFF METHODS. U.S. Pat. No. 7,012,519 This system allows a new vehicle or equipment to have a remote controller of the ignition circuit installed, without cutting or damaging the wire harness. This system will not void the manufacture warranty of engine module or computer system. This system will shorten the time required to install our “FOX-PAWS” shut down switch, thus saving the customer time and money.

Abstract: Method for the duplication of original electronic keys used in the automotive transports, and provided with coded and encrypted electronic authentication means, comprising: an Identification Code (ID), an encrypted secret code, a Password, an algorithm, data storage and computing means, able of being used in vehicles provided with a central processing unit able of storing an Identification Code (ID), an encrypted secret code, a Password, an algorithm, said duplication method being able of obtaining a duplicated key based on a blank key, which is originally provided with an algorithm, data storage means able of storing said Identification Code (ID), said secret code and said Password, wherein said data storage means are initially empty; said duplication is based on a duplication means and on a method which allows of using the blank key as intercepting means of secret codes sent by the vehicle central processing unit, and of transferring said information to the duplication means itself.

Abstract: Disclosed is a mobile terminal capable of converting an operational state of a controller thereof upon generation of a preset event and controlling an operational state of a particular terminal having a communication connection under control of the controller, and a control method thereof, the control method for controlling power functions within a vehicle telematics control unit comprising: accessing stored voltage information for a battery included in a vehicle; determining a present voltage characteristic of the battery based on measurements of voltage; determining whether a difference exists between the stored voltage information and the present voltage characteristic; converting an operational state of a vehicle telematics control unit responsive to determining that a difference exists; accessing threshold information associated with the battery; comparing the present voltage characteristic of the battery to the threshold information; determining whether the present voltage characteristic of the battery

Abstract: A starter relay structure for a vehicle, where an electronic control unit of the vehicle controls the starter relay structure. The starter relay structure comprises a first relay and a second relay activated by an ignition signal from the electronic control unit. The starter relay structure further include a third relay activated by an output of the second relay, where an output of the first relay is provided as an input to the third relay.

Abstract: An integrated exciter-igniter architecture is disclosed that integrates compact, direct-mounted exciter electronics with an aerospace designed igniter to reduce overall ignition system complexity. The integrated exciter-igniter unit hermetically seals exciter electronics within a stainless steel enclosure or housing. The stainless enclosure enables the exciter electronics to remain near atmospheric pressure while the unit is exposed to vacuum conditions. The exciter electronics include a DC-DC converter, timing circuitry, custom-designed PCBs, a custom-designed main power transformer, and a high voltage ignition coil. All of which are packaged together in the stainless steel enclosure. The integrated exciter-igniter unit allows for efficient energy delivery to the spark gap and eliminates the need for a high voltage cable to distribute the high voltage, high energy pulses.

Abstract: An input circuit includes an interface structured to output a logic signal from an alternating current signal of a pair of elongated conductors. A load is switchable to the elongated conductors. A processor outputs a control signal to switch the load to the elongated conductors asynchronously with respect to the alternating current signal for a first predetermined time, inputs the logic signal, determines if the input logic signal is active a plurality of times during the first predetermined time and responsively sets a first state of the alternating current signal, and, otherwise, sets an opposite second state of the alternating current signal, and delays for a second predetermined time, which is longer than the first predetermined time, for the opposite second state before repeating the output, and, otherwise, delays for a third predetermined time, which is longer than the second predetermined time, for the first state before repeating the output.

Abstract: A vehicle system includes a switch that is movable between first and second positions in a linear direction and moveable between third and fourth positions in a rotational direction. The system also comprises a control module that responds to the switch when the switch is in both the second position and the fourth position. The control module does not respond to the switch being moved from the third position to the fourth position unless the switch is also moved from the first position to the second position.

Abstract: In a hybrid vehicle which has a plurality of drives, of which in particular one drive is a combustion engine and the other is an electric drive, all the drive control units, if appropriate even a transmission control unit, require enabling by an immobilizer control unit before the first control unit outputs control commands to communicate a torque request, input by a vehicle driver.

Abstract: A motor vehicle electrical system having a starter and a first energy store, which are arranged in a first region of the motor vehicle electrical system, and a generator and a second energy store, which are arranged in a second region of the motor vehicle electrical system, wherein, a switching element is arranged between the first and the second region of the motor vehicle electrical system, wherein the switching element has at least two switching states, wherein, in a first switching state, a current can flow only from the first region toward the second region and, in a second switching state, the first and second region have a through-connection to one another, wherein the second energy store is connected to the generator via a DC/DC converter, wherein, via a second switching element, the starter is connected directly to the second energy store.

Abstract: A keyless ignition start system in which authentication of a coded key fob is carried out twice, first to activate the ignition switch to allow starting the engine and second at the time when the brake pedal is depressed to put the car in a drive gear. The two step authentication prevents driving off a car which has been started without having the key fob for security purposes and also to avoid inconvenient situations that can otherwise occur.

Abstract: A method for maintaining a predetermined voltage in a battery-supported vehicle electrical system during the operation of an electrical starter includes steps of operating the electrical starter on the vehicle electrical system during a first time phase in series with a limiting resistor, in order to limit the current flowing through the starter, and operating the electrical starter on the vehicle electrical system during a second time phase with a reduced limiting resistance, in order to increase a power converted by the starter. A transition from the first time phase to the second time phase is controlled on the basis of electrical parameters sampled during the first time phase at the limiting resistor.

Abstract: The intent of this invention is to minimize the possibility of exhausting the vehicle battery while still permitting operation of specific accessories with the engine off. The invention proposes to accomplish this by powering and terminating the operation of an accessory through and under the control of any type of no idle HVAC system or as a free standing auxiliary, accessory powering system having its own means of termination.

Abstract: An electric system for a motor vehicle and method for control of a starter motor (10) and a battery isolator (11) in such an electrical system. A consumer battery set and a starting battery set (6) are connected in parallel. The battery isolator is switchable between an off position in which the starting battery set is electrically disconnected from the starter motor, and an on position in which the starting battery set is electrically connected to the starter motor. An electronic control device (12), upon receiving a starting signal, causes the battery isolator to assume the on position, and thereafter causes the starter motor to start, in order thereby to ensure that the battery isolator is in the on position before the starter motor is started.

Abstract: A voltage stabilization device is proposed for use in a motor vehicle. The voltage stabilization device comprises a first terminal for connecting the device with an energy source, in particular to a vehicle battery; a second terminal for connecting the device having a starting device of a motor vehicle; a current limiter module for limiting a starting current; a control unit for controlling the current limiting module, and at a starting operation detector coupled with the control unit for detecting a starting operation, wherein the current limiting module carries out a starter current limiting action on the basis of a start signal of the process startup detector.

Abstract: A device (1) for stabilising a supply voltage (UBatt) in a motor vehicle, having a function component of the motor vehicle, in particular in the form of a starter (4), a voltage source (10) which is connected to the function component (4) in order to supply the function component (4) with the supply voltage (UBatt) characterised in that the voltage source (10) is connected to the function component (4) via a resistor cascade (30) in order to stabilise the supply voltage (UBatt).

Abstract: An internal power circuit lowers a battery voltage supplied always from an external side to generate a standby power voltage. A timer continues to measure an elapse of time in a standby state, after a main relay is turned off and supply of a power voltage is interrupted. A measured time data of the timer is saved to a save register during a time measurement operation of the timer. When a stop condition for stopping the time measurement operation of the timer is satisfied, a control circuit stops the operation of the internal power circuit. When the main relay is turned on, the internal power circuit is activated to start its operation again by the control circuit so that the measured time data saved to the save register is restored to the timer.

Abstract: The present invention provides a power-supply device, which can continuously supply a voltage from a power supply to a load even if a breakdown of a circuit is generated. The power-supply device includes a booster circuit, a normally-closed bypass relay, a CPU, and a switching circuit. A first switch of the switching circuit is turned on by a switching signal from the CPU, and a second switch is turned on by a boosting request signal from a boosting request signal generator. In the case that one of or both the switching signal and the boosting request signal are not input to the switching circuit 14, because a coil of a bypass relay is not energized, a contact turns on, and a voltage is supplied from a DC power supply to the load through the contact.

Abstract: A power supply control apparatus for controlling a power supply unit including a battery and a load is provided. The power supply control apparatus includes a main relay and a ground relay, a pre-charge relay, an inrush current limiting resistor, a first relay control section, and a time measurement section. The main relay and the ground relay are connected between the battery and the load. The pre-charge relay is connected in parallel with one of the main relay and the ground relay. The inrush current limiting resistor is connected in series with the pre-charge relay, and limits an inrush current from the battery to the load. The first relay control section temporarily turns ON the pre-charge relay and turns ON the main relay and the ground relay upon receiving a power supply connection request from the outside, and turns OFF the main relay and the ground relay upon receiving a power supply interruption request from the outside.

Abstract: A charging device for an electrically-drivable vehicle comprises a power-supply connector (100), a power-receiving connector (200), a safety-charging-signal-generating unit provided in the charging device, a CAN control module receiving a safety-charging signal generated by the safety-charging-signal-generating unit. The charging device may be configured to be chargeable to the electrically-drivable vehicle when the charging terminal and the charging-terminal-accommodating chamber are connected to each other. The power-supply connector and the power-receiving connector are engaged with the CAN module detecting the safety-charging signal. The personal safety during maintenance or other unexpected accidents is enhanced.

Abstract: A engine control unit comprises: a three-phase bridge circuit that has a first end connected to the first end of the first load and a second end connected to a ground, the three-phase bridge circuit performing commutation control on an alternating-current power supplied from the motor generator or driving the motor generator; a DC-DC converter connected between the first end of the three-phase bridge circuit and a second end of the control switch; a diode that has an anode connected to the battery connecting terminal and a cathode connected to the second end of the control switch; a voltage detecting circuit that detects a voltage of the battery connecting terminal; a first switch element connected between a second end of the coil and the ground; a second switch element connected between a second end of the first load and the ground; and a control circuit.

Abstract: A power-supply device has a DC power supply, a load, a booster circuit disposed between the DC power supply and the load, wherein the booster circuit supplies a voltage at the DC power supply to the load while boosting the voltage, a bypass element disposed between the DC power supply and the load, wherein the bypass element constitutes a bypass path with respect to the booster circuit, a controller that controls an operation of the booster circuit, a first switching element that drives the bypass element in a first driving path, and a second switching element that drives the bypass element in a second driving path.

Abstract: A system for controlling the operation of performing emergency notification in a vehicle is provided. The system comprises a controller configured to receive at least one driver status signal indicative of whether the driver is one of the primary driver and the secondary driver from a key ignition device positioned on at least one of a primary key and the secondary key. The controller is configured to determine whether the driver of the vehicle is one of the primary and the secondary driver based on the at least one driver status signal. The controller is configured to selectively control the operation of performing emergency notification based on whether the driver of the vehicle is one of the primary driver and the secondary driver.

Abstract: A vehicle, such as a car, includes an airbag deployment system and a vehicle systems controller. The vehicle systems controller can connect the airbag deployment system to a reserve power source for a predetermined period of time when a battery terminal voltage falls below a predetermined threshold.

Abstract: A driver authentication and safety system and method for monitoring and controlling vehicle usage by high-risk drivers. A centralized database comprising a software application can be accessed by an authorized user via a data communications network utilizing a remote computer in order to configure a desired operating profile that matches requirements of the high-risk driver. The operating profile can be loaded to a driver identification and data logging device in conjunction with the remote computer. A master control unit receives a unique identification code from the data logging device to authenticate the high-risk driver and to operate the vehicle within the desired operating profile. A slave control unit receives commands from the master control unit and generates a real time alarm signal if the driver violates the preprogrammed operating profile unique to the driver.

Abstract: The SOC of a power storage device provided in an electrically powered vehicle is controlled not to fall out of a SOC control range. When a SOC estimate value reaches a control lower limit value during vehicle traveling, a power generating structure provided in the vehicle starts to charge the power storage device. In the case of low temperature and/or deterioration of the power storage device, i.e., in the case where decrease of performance of the power storage device is concerned, the control lower limit value is increased as compared with that in a normal state. As a result, decrease of driveability and decrease of startability of an engine in the hybrid vehicle, both otherwise caused by insufficient output electric power from the power storage device, can be avoided.

Abstract: A seat has a seat frame and a seat cushion supported by the seat frame. The seat cushion has an upper surface that supports a user and a lower surface defining a cavity. The seat cushion moves between an at rest condition in which no operator is seated on the seat, and a deflected condition in which the seat cushion is deflected with respect to the frame in response to an operator seated on the seat. A switch is mounted to the frame and opens and closes an electrical circuit in response to an actuating force. A switch actuator is mounted to the seat cushion lower surface in the cavity and moves between a non-actuating position when the seat is at rest and an actuating position when the seat is deflected. The switch actuator delivers the actuating force as the switch actuator is moved toward the actuating position.

Abstract: An engine control unit for driving an electric circuit, e.g., a starter in a vehicle, includes at least a first element for making a first signal, particularly an ignition signal, available, a second element for making a voltage available for the electric circuit, a third element for connecting the electric circuit, a first switch which is disposed between the second and third elements to control the electric, circuit, and a fourth elements for generating a second signal, the first signal cooperating with the second signal to form a virtual second switch for turning the electric circuit on or off with the aid of the first switch.

Abstract: When a highly accurate clock is received by a GPS radio wave from a GPS antenna, the highly accurate clock is always generated by locking a phase locked loop (PLL) circuit within a hold-over section of a clock control section in a power supply control unit. When the GPS radio wave cannot be received normally, the highly accurate clock depending on the GPS radio wave is set to a self-running condition not depending on a self-oscillation clock from an internal clock generating section and a time management section automatically corrects the present time data obtained when the standard radio wave is received from a radio wave antenna based on the highly accurate clock. A primary voltage generating section continuously generates the highly accurate clock even when an ignition switch is turned OFF by avoiding voltage variation in battery voltages while the ignition switch is turned ON.

Abstract: An input circuit includes an interface structured to output a logic signal from an alternating current signal of a pair of elongated conductors. A load is switchable to the elongated conductors. A processor outputs a control signal to switch the load to the elongated conductors asynchronously with respect to the alternating current signal for a first predetermined time, inputs the logic signal, determines if the input logic signal is active a plurality of times during the first predetermined time and responsively sets a first state of the alternating current signal, and, otherwise, sets an opposite second state of the alternating current signal, and delays for a second predetermined time, which is longer than the first predetermined time, for the opposite second state before repeating the output, and, otherwise, delays for a third predetermined time, which is longer than the second predetermined time, for the first state before repeating the output.

Abstract: A battery with an embedded battery management system is disclosed. The battery management system facilitates various advantages including monitoring the operational characteristics of individual battery cells, performing passive and/or active cell balancing, calculating the remaining life of the battery, and providing a warning if the battery is near the end of its life. The embedded battery management system also facilitates making battery parameters available externally, interfacing with smart charging systems, and enabling the battery management system to control the smart charging system, for example by making desired charge requests. The embedded battery management system includes non-volatile memory that stores algorithms for implementing different functions of the battery management system.

Abstract: An electronic circuit includes an electronic switch with a control terminal and a load path between a first and a second load terminal, and a drive circuit with an output terminal coupled to the control terminal of the electronic switch. The drive circuit includes a first input terminal and a second input terminal, a first drive unit coupled between the first input terminal and the output terminal and including a charge pump and drive unit, and a second drive unit coupled between the second input terminal and the output terminal and including a further electronic switch coupled between the output terminal and a terminal for a reference potential.

Abstract: A battery system for a motor vehicle is disclosed. The battery system includes an internal combustion engine, said battery system comprising at least one starting circuit, a low-voltage on-board supply system, and an on-board supply system with an increased voltage. The starting circuit has a starter battery and a starter that is connected, or can be connected, to the starter battery, said starter being used to start the internal combustion engine on a starter signal. The low-voltage on-board supply system has an on-board supply system battery used to produce a first voltage and to transmit same to the low-voltage on-board supply system, and at least one electrical consumer . The on-board supply system with increased voltage has at least one electric generator that can be operated by the internal combustion engine and is used to produce a second voltage higher than the first voltage and to transmit said second voltage to the on-board supply system with increased voltage.

Abstract: Methods and apparatus are provided for performing a jump-start without the use of external equipment. The apparatus comprises a first battery electrically coupled to a starter motor for an engine, the first battery providing power to start the engine; a second battery; a power converter electrically coupled to the first battery and electrically coupled to the second battery; and a controller communicatively coupled to the power converter. The controller may be configured to determine a low battery condition of the first battery such that the first battery has insufficient power to start the engine, and when the low battery condition occurs, to direct the power converter to supply power from the second battery to the first battery to thereby allow the engine to be started.

Abstract: A vehicular power system, which has an operating switch for making the transition among an ON state in which an IG power is ON or a vehicular power source is ON, an ACC state which is different from the ON state and in which an accessory power is ON, and an OFF state in which the vehicular power source and the accessory power are OFF, wherein when the operating switch is operated while a shift lever is in a parking position in the ACC state after the transition from the OFF state, the transition is made from the ACC state to the ON state.

Abstract: The accuracy of measuring the temperature of a semiconductor element is improved, while a method for measuring the temperature using a general-purpose semiconductor element is provided at low cost. A fourth conductor that is a part of a first conductor connected to a power semiconductor element and is a thin line pattern extends under a chip thermometer. The fourth conductor and the thermometer are connected to each other through high thermal conductive resin.

Abstract: The invention relates to an electric circuit for an automobile, that comprises a ground line (M), an onboard network (R) with a battery (1) connected to the network (R) and to the ground (M) by a branch (b1) comprising a switch (K1) and by a second branch (b2) including a switch (K2), an alternator (3) connected to the battery, a starter and consumer members (4) connected to said onboard network and to the ground. The circuit further includes a voltage holding device that comprises a bridge (b3) connecting the branch (b1) to the branch (b2) and a capacitor (2) connected to the bridge (b3) at a location between the third switch (K2) and the second branch (b2), and an internal supply device (8) that allows the current flow in the second branch (b2) only when recharging the capacitor (2).

Abstract: In one embodiment there is a remote starter system for a vehicle having an ignition connected to vehicle controllers by a serial data interface. The remote starter system includes a T-Harness connector having at least a first, second, and third serial data connectors and a remote starter module. The remote starter module having at least a remote starter connector, wherein the first serial data connector of the T-Harness connector is coupled to the remote starter connector, and the second and third serial data connectors are separately coupled between the pair of interconnected vehicle serial data connectors. Data from the remote starter module is thereby communicated to the vehicle controller modules and the ignition module.

Abstract: An engine starting device for controlling an engine start of a vehicle by driving a starter relay of the vehicle with a battery of the vehicle as a power supply has a control processing unit and a step-up circuit for stepping up the output of the battery and outputting a drive voltage for driving the control processing unit and the starter relay.

Abstract: An integrated magnetic switch assembly includes a winding assembly portion having a housing, and a cover assembly mounted to the housing. The cover assembly includes at least one rivet terminal and at least one power terminal The at least one rivet terminal includes a body that extends through the cover assembly. The body has a first end that extends to a second end, and an opening that includes a first diameter that extends from the first end to the second end. A sealing member is positioned at the first end of the body about the opening of the at least one rivet terminal. The sealing member includes an opening having a second diameter that is smaller than the first diameter. A sealing element is positioned between the at least one power terminal and the cover assembly.

Abstract: A starter for an auxiliary power unit includes a direct current motor operably connectable to an auxiliary power unit. A clutch is arranged in an electrically parallel relationship and configured to operably connect the motor to the auxiliary power unit when engaged, the motor and the clutch powered by a common input line. A time delay switching element is located and configured to delay power delivery to the direct current motor thus providing for full engagement of the clutch prior to initiation of rotation of the motor.

Abstract: A starter relay structure for a vehicle, where an electronic control unit of the vehicle controls the starter relay structure. The starter relay structure comprises a first relay and a second relay activated by an ignition signal from the electronic control unit. The starter relay structure further include a third relay activated by an output of the second relay, where an output of the first relay is provided as an input to the third relay.

Abstract: A simulation tool includes a printed circuit board assembly or PCBA having a built-in USB communication port and a microcontroller. A host computer transmits user-selected configuration data to the microcontroller, which transforms the data into solid-state signals. These are provided to a power master module in an electrical bench or a test vehicle. A method of simulating a low-current ignition switch that is usable with the PMM includes transmitting user-selectable configuration data from a host computer to a PCBA having a microcontroller, transforming the configuration data into a set of solid-state signals simulating a desired set of power mode parameters, and transmitting the solid-state signals to the PMM to thereby simulate an operation of the low-current ignition switch.

Abstract: In one embodiment, a power cell chamber for a drive system includes moveable and fixed portions. The moveable portion includes a rectifier stage to rectify an input signal received from a secondary winding of a transformer to provide a rectified signal and an inverter stage having a plurality of switching devices to receive a DC signal and output an AC signal. This moveable portion can be slidably adapted within a cabinet of the drive system. In turn, the fixed portion includes a DC link having at least one capacitor to receive the rectified signal and provide the DC signal to the inverter stage.

Abstract: A security device for a means of transport comprising a radiation source to direct radiation into the eye of a person intending to take control of the means of transport, so that the radiation is internally reflected within the eye and emerges from the eye with a substantial spectral content corresponding to the spectral content of food flowing through the retina of the eye, and a receiver arrangement to receive the radiation emanating from the eye of the person and to perform a spectral analysis of the reflected radiation to determine the concentration of at least one chemical within the blood of the person, the device further comprising an alarm unit to generate an alarm and/or an immobilizer unit to immobilize the means of transport, the or each unit being responsive to the said determination of concentration when the concentration of the said chemical is outside a permitted threshold range.

Abstract: A remote climate control system is for a hybrid vehicle having a rechargeable electrical power source and an electrical ventilation blower selectively powered thereby, a sensor associated with the rechargeable electrical power source, and a data communications bus extending throughout the hybrid vehicle. At least one of the electrical ventilation blower and the sensor is coupled to the data communications bus. The remote climate control system includes a remote transmitter and a receiver to be positioned at the hybrid vehicle for receiving signals from said remote transmitter. A vehicle remote climate controller cooperates with said receiver and to be coupled to the data communications bus extending within the hybrid vehicle for communication thereover to selectively operate the electrical ventilation blower responsive to the sensor and said remote transmitter.

Abstract: A starting system for an internal combustion engine includes a starter motor configured to transfer torque to the engine during an engine starting event, a low-voltage power bus including a first bus segment and a second bus segment, a controllable isolation circuit including a first state wherein the first and second bus segments are electrically coupled and a second state wherein the first and second bus segments are electrically isolated, a low-voltage battery and the starter motor electrically coupled to the first bus segment, an accessory power module and a power supply for a control module electrically coupled to the second bus segment; and the control module configured to control the isolation circuit to the second state to electrically isolate the first bus segment from the second bus segment during the engine starting event.

Abstract: The engine starting apparatus operates on battery voltage when the battery voltage is higher than a predetermined voltage to control starting of an engine of a vehicle. The engine starting apparatus includes a relay control section configured to output a drive signal individually to first and second relays of a starter of the vehicle engine to drive the first and second relays when predetermined engine start conditions are satisfied, the starter being configured to operate when the first and second relays are driven, and an inter-relay switch configured to make electrical connection between the first and second relays when the first relay is applied with the battery voltage, the second relay being applied with the battery voltage when the electrical connection is made. The first relay is configured to be applied with the battery voltage when a manual start switch is operated.