A heat exchange module having a first heat exchanger, configured to enable heat exchange between a first fluid and a flow of air and extending inside a first plane of overall extension, and a second heat exchanger, configured to enable heat exchange between a second fluid and the flow of air and extending inside a second plane of overall extension, is disclosed. A housing delimiting, with the first heat exchanger, a circulation channel for the flow of air is included. The module has at least one air distribution member, movable between a position in which the air distribution member allows the flow of air to pass through the first heat exchanger and the second heat exchanger, and a position in which the air distribution member prevents the flow of air from passing through the first heat exchanger while allowing the flow of air to pass through the second heat exchanger.

An apparatus includes a housing configured to receive at least a portion of an electric motor. The apparatus also includes a manifold disposed on an upper surface of the housing. The manifold includes a number of vertical jets configured to target one or more portions of the electric motor, the vertical jets includes multiple vias extending between (i) a cavity within the manifold and (ii) an interior portion of the housing. The cavity within the manifold is defined by (i) at least a portion of the upper surface of the housing, (ii) one or more side walls extending from the upper surface of the housing, and (iii) a cover lid coupled to the one or more side walls and configured to cover the cavity and the vias.

A vehicle for activating launch control in response to establishment of a predetermined activation condition includes an electric power conversion device configured to control electric power supplied to an electric motor, the electric motor configured to drive a driven wheel according to electric power supplied via the electric power conversion device, a temperature control circuit in which a temperature control medium circulates to control a temperature of the electric power conversion device, and a control device. The temperature control circuit includes a pump configured to pump the temperature control medium. The control device is configured to control the pump, and when the activation condition is established, the control device is configured to control the pump such that a flow rate of the pump is high as compared with a case where the activation condition is not established.

A vehicle for activating launch control in response to establishment of a predetermined activation condition includes an electric power conversion device configured to control electric power supplied to an electric motor, the electric motor configured to drive a driven wheel according to electric power supplied via the electric power conversion device, a temperature control circuit in which a temperature control medium circulates to control a temperature of the electric power conversion device, and a control device. The temperature control circuit includes a pump configured to pump the temperature control medium. The control device is configured to control the pump, and when the activation condition is established, the control device is configured to control the pump such that a flow rate of the pump is high as compared with a case where the activation condition is not established.

An electrified drive train for a motor vehicle, having a heat generator, includes at least one electrical drive machine, and a heat dissipation circuit which has at least one first heat exchanger and one second heat exchanger for dissipating heat from a cooling circuit which is routed through the heat generator. During operation, a fluid used in the heat dissipation circuit flows through the first heat exchanger and, parallel thereto, through the second heat exchanger.

An electrified drive train for a motor vehicle, having a heat generator, includes at least one electrical drive machine, and a heat dissipation circuit which has at least one first heat exchanger and one second heat exchanger for dissipating heat from a cooling circuit which is routed through the heat generator. During operation, a fluid used in the heat dissipation circuit flows through the first heat exchanger and, parallel thereto, through the second heat exchanger.

A cooling circuit for a vehicle includes a single cooler, a refrigeration machine, a first heat-generating device, a second heat-generating device, a coolant pump arrangement configured to pump a coolant, a valve arrangement, and an electronic control module. The first heat-generating device requires the coolant at a first coolant temperature level. The second het-generating device requires the coolant at a second coolant temperature level. The valve arrangement is configured to supply the coolant from the first and second heat-generating devices to the refrigeration machine and/or to the single cooler. The electronic control module is designed to control a temperature of the coolant at coolant inlets of the first and second heat-generating devices by varying flow rates of the coolant through the refrigeration machine and/or the single cooler.

A lower structure for a hybrid automobile in which a high-voltage battery is disposed in a lower surface of a floor panel includes an engine exhaust system component which is disposed in front of the high-voltage battery in the lower surface of the floor panel and on one vehicle-width-direction side of a center in a vehicle width direction and high-voltage devices which are disposed in front of the high-voltage battery and on another vehicle-width-direction side of the center in the vehicle width direction. In-vehicle equipment is disposed between the high-voltage battery and the high-voltage devices, and the in-vehicle equipment is in an inclined state where an upper surface of the in-vehicle equipment is inclined in a front-rear direction such that the in-vehicle equipment has a shorter dimension in the front-rear direction than a dimension in a horizontal state where the upper surface becomes horizontal.

A coolant connection structure includes an upper body fastened to an upper end portion of the vehicle, a lower body positioned at a lower end portion of the upper body, a floor panel formed between the upper body and the lower body, and a joint module positioned at the floor panel and fluidly connected to a coolant tank positioned at the lower body.

A coolant connection structure includes an upper body fastened to an upper end portion of the vehicle, a lower body positioned at a lower end portion of the upper body, a floor panel formed between the upper body and the lower body, and a joint module positioned at the floor panel and fluidly connected to a coolant tank positioned at the lower body.