An electronic switching module for connecting first and second throttle assemblies to an electronic control module of a vehicle that controls an engine of the vehicle includes first throttle assembly ports adapted to receive first throttle primary sensor position data and first throttle secondary sensor position data and second throttle assembly ports adapted to receive second throttle primary sensor position data and second throttle secondary sensor position data. A controller is connected to the first and second throttle assembly ports and an electronic control module port and is adapted to receive and compare the first throttle primary sensor position data and the first throttle secondary sensor position data and send an engine idle signal to the electronic control module via the electronic control module port when the comparison does not show a first predetermined relationship. The controller is also adapted to receive and compare the second throttle primary sensor position data and the second throttle secondary sensor position data and send an engine idle signal to the electronic control module via the electronic control module port when the comparison does not show a second predetermined relationship.

A throttle operating device includes a fixing member, a throttle lever, the throttle lever, a magnet which is configured to rotate in response to a rotational operation of the throttle lever, and a detection sensor. A drive source of the vehicle is configured to be controlled based on the rotational operation angle of the throttle lever detected by the detection sensor. A magnetic shielding unit is disposed in the fixing member and configured to cover a periphery of the magnet and the detection sensor to shield magnetism from the outside.

A torque requesting module generates a first torque request for a spark ignition engine based on driver input. A torque conversion module converts the first torque request into a second torque request. A setpoint control module generates air and exhaust setpoints for the spark ignition engine based on the second torque request. A model predictive control (MPC) module identifies sets of possible target values based on the air and exhaust setpoints, generates predicted parameters based on a model of the spark ignition engine and the sets of possible target values, respectively, selects one of the sets of possible target values based on the predicted parameters, and sets target values based on the possible target values of the selected one of the sets. A throttle actuator module controls opening of a throttle valve based on a first one of the target values.

A method of exercising a generator includes detecting a temperature of the generator by a temperature sensor, if the temperature of the generator is above a predetermined temperature, activating, by a controller, a starter motor of the generator, and performing, by the controller, an exercise test, and if the temperature of the generator is below the predetermined temperature, not activating, by the controller, the starter motor.

A method for diagnosing a waste gate valve malfunction in a power generation system is presented. The method includes determining an actual pressure differential across a throttle valve. The method further includes determining an estimated pressure differential across the throttle valve based on one or more first operating parameters of the power generation system. Furthermore, the method includes determining an absolute difference between the actual pressure differential and the estimated pressure differential. Moreover, the method also includes comparing the absolute difference with a threshold value and if the absolute difference is greater than the threshold value, determining an operating condition of the throttle valve. Additionally, the method includes determining whether the waste gate valve has malfunctioned based on the determined operating condition of the throttle valve. An engine controller and a power generation system employing the method are also presented.

A system for controlling a vehicle fitted with electrical controls, the control system includes a handgrip mounted on a shaft and fitted with a position sensor and with a return spring which is fixed by one end to the handgrip so as to generate a return moment that opposes the twisting of the handgrip. The system includes at least one actuator able to move a cam mounted on the shaft and able to: modify the preload of the return spring according to the position of the cam to which the other end of the return spring is fixed, and/or modify the travel of the handgrip by collaborating with an end stop of the handgrip, the end stop coming into contact with a cam at the end of the travel.

A gasket sandwiched between an opening of a first member and an opening of a second member. The gasket comprises a first gasket substrate including a first bead protruding along a peripheral edge of a first opening portion disposed corresponding to the opening of the first member and toward a side of the first member, the first gasket substrate being disposed on a side of the first member. A second gasket substrate including a second bead protruding along a peripheral edge of a second opening portion disposed corresponding to the opening of the second member and toward a side of the second member, the second gasket substrate being disposed on a side of the second member, and an intermediate substrate interposed between the first gasket substrate and the second gasket substrate. The intermediate substrate includes a through-hole having a predetermined width and a predetermined length formed along a longitudinal direction of the first bead and the second bead in a portion facing the first bead and the second bead.

An exhaust gas control apparatus for an internal combustion engine includes: a catalyst which is capable of storing oxygen; a downstream air-fuel ratio sensor that detects the air-fuel ratio of outgoing exhaust gas flowing out of the catalyst; an air-fuel ratio control unit that controls the air-fuel ratio of incoming exhaust gas flowing into the catalyst; and a catalyst state estimation unit that estimates the activity of the catalyst. The air-fuel ratio control unit controls the air-fuel ratio of the incoming exhaust gas so that the air-fuel ratio of the outgoing exhaust gas detected by the downstream air-fuel ratio sensor is maintained at a target air-fuel ratio. The air-fuel ratio control unit sets the target air-fuel ratio to a richer value when the activity of the catalyst is equal to or higher than a predetermined value than when the activity of the catalyst is lower than the predetermined value.

A system for controlling a vehicle fitted with electrical controls, the control system includes a handgrip mounted on a shaft and fitted with a position sensor and with a return spring which is fixed by one end to the handgrip so as to generate a return moment that opposes the twisting of the handgrip. The system includes at least one actuator able to move a cam mounted on the shaft and able to: modify the preload of the return spring according to the position of the cam to which the other end of the return spring is fixed, and/or modify the travel of the handgrip by collaborating with an end stop of the handgrip, the end stop coming into contact with a cam at the end of the travel.

A simple and effective control method is disclosed for starting and stopping a vehicle's engine and automatic lighting of position lamps to show the vehicle's location. The method uses brake and gear shift lever of the vehicle to generate selection signals, and a button switch can be pressed to stop or start the engine of the vehicle according to the selection signals, which can provide vehicle drivers a simple and secure way to control their vehicles while waiting at a stoplight.