Vehicle roof structure with integrated electrical connectivity module and methods for making the same are disclosed. For one example, the vehicle roof structure includes a plurality of pre-assembled components and an electrical connectivity module. The pre-assembled components include a plastic panel which covers a first compartment integrated into the roof structure that houses the electrical connectivity module below the plastic panel. The electrical connectivity module can be coupled to an antenna system that provides radio or cellular communications. The antenna system can be attached to the plastic panel. The electrical module can include a plurality of modems that can receive and transmit radio or cellular signals. An advanced driver assistance systems (ADAS) module can be housed in a second compartment integrated into the roof structure. The roof structure including the electrical connectivity module or ADAS module can be attached to a body frame of a vehicle. The plastic panel protects the electrical connectivity module while not creating a barrier for radio or cellular communications of the antenna system. The roof structure can be an aluminum roof structure, a fixed full glass roof structure, a fixed half glass roof structure or a movable sun structure.

A vehicle front portion structure includes: a pair of front side members extending in a vehicle front-rear direction, the front side members being disposed at an interval in a vehicle width direction; an MC cross-member suspended between the front side members, the MC cross-member being provided with a front cross portion extending in the vehicle width direction and a rear cross portion provided behind the front cross portion and extending in the vehicle width direction; and motor mounts configured to connect a high-voltage component to the MC cross-member, the motor mounts being suspended between the front cross portion and the rear cross portion.

A hybrid module shipping assembly includes a hybrid module configured for arrangement in a torque path upstream from a transmission and downstream from an internal combustion engine. The hybrid module includes a hybrid drive unit, a housing fixed to a front side of the hybrid drive unit and a torque converter fixed to a rear side of the hybrid drive unit. The torque converter includes an impeller hub. The hybrid module shipping assembly also includes a cap assembly inserted in the impeller hub and a shipping dome fixed to the housing such that the housing and shipping dome encase the hybrid drive unit, the torque converter and the cap assembly.

A vehicle body structure includes a first middle floor unit for a gasoline vehicle and a second middle floor unit for a hybrid vehicle, and the first and second middle floor units are made interchangeable with each other. A front floor unit and a rear floor unit are made shareable by the gasoline vehicle and the hybrid vehicle. That is, the front floor unit and the rear floor unit can be regarded as a platform. Additionally, the second middle floor unit includes a housing, and an IPU is stored in an interior of the housing.

A hybrid vehicle drive apparatus, including a prime-mover-output-shaft, a transmission-input-shaft and a motor-rotor provided therebetween, each rotatable around an axis-line, a first-clutch connecting/disconnecting the output-shaft and the motor, a second-clutch connecting/disconnecting the motor and the input-shaft, a case-member having a radially extending non-rotating-sidewall-member and a non-rotating-shaft-member extending around the axis-line, and a rotor-support-member having a rotating-shaft-member rotatably fitted on the non-rotating-shaft-member and a rotating-sidewall-member facing the non-rotating-sidewall-member and extending radially outward from the rotating-shaft-member, and cantilevering the rotor, wherein the first/second-clutch has first/second-plates alternately and rotatably arranged in the axial-direction, a clutch-hub supporting the first-plates movably in the axial-direction, and a clutch-drum supporting the second-plates movably in the axial-direction, the clutch-hub of the first-clutch is integrally rotatable with the output-shaft, the clutch-hub of the second-clutch is integrally rotatable with the input-shaft, and the clutch-drums of the first/second-clutches are a single-shared-clutch-drum and integrally rotatable with the rotor-support-member.

Some embodiments relate to a vehicle corner module (VCM) connectable to a VCM-connection interface of a reference-frame of a vehicle platform (e.g. for regulating motion of a vehicle). Some embodiments relate to a multi-interface connection-element for connection of multiple electronic or flow vehicle subsystems of a vehicle to a Vehicle Corner Module (VCM). Related methods are disclosed herein.

A clutch device, comprising a first input side coupled to a first drive motor, a second input side coupled to a second drive motor, a first and second output side, wherein the first and second output sides can and the first and second input sides can be rotated about a common axis. The clutch device further includes a first clutch located between the first input side and the first output side, a second clutch located between the first input side and the second output side, and a third clutch located between the first input side and the second input side, wherein the third clutch is arranged offset relative to the first clutch.

A hybrid drive system for an auxiliary load includes a hydraulic auxiliary power storage. This hydraulic auxiliary power storage has a plurality of hydraulic power storage units. The hybrid drive system further comprises an power exchange control system that selectively connects a predetermined selection of one or more of the hydraulic power storage units to the hydraulic auxiliary power unit; and controls the power exchange of the auxiliary power unit as a function of the operating period by the predetermined selection.

A drive unit (1) has a housing (2) and an output-side element (3). The housing (2) has at least two webs (8) that lie opposite one another and that project from the housing (2) in a manner so that the webs (8) are spaced apart from one another. The webs (8) are configured to fasten the housing (2) to a mounting unit (7).

A traction energy storage system including multiple electrical energy stores and a system controller. Each of the energy stores includes one or more cell modules electrically connected via busbars, an energy store high-voltage interface connectable to the busbars and an energy store controller controlling the cell modules. Each of the cell modules comprises multiple storage cells and a cell module controller. Each of the cell module controllers is configured to output measured values relating to the storage cells in the respective cell module to the energy store controller. Each of the energy store controllers is configured to take the measured values obtained as a basis for generating signals having electrical characteristic quantities of the respective energy store and at least one limit value for a current through the energy store high-voltage interface of the respective energy store.