COLUMN MOUNTED CAMERA

CROSS-REFERENCE TO RELATED APPLICATIONS

[0001] This PCT application claims the benefit of priority under 35 U.S.C. §1 19 to United States Provisional Application No. 62,852,737, filed May 24, 2019, the contents of which are incorporated herein by reference in their entirety.

FIELD OF THE INVENTION

[0002] The present application generally relates to camera assembly for mounting in the interior of a motor vehicle.

BACKGROUND

[0003] Present motor vehicles incorporate numerous features for the control of vehicle functions and to provide a comfortable environment for vehicle occupants while providing access to information, media and communication functions. Another primary objective is to provide occupant protection. Occupant protection approaches can be divided into two primary areas; active and passive safety. Passive safety features include inflatable restraints, seatbelts and other functions deployed upon the occurrence of a vehicle impact or rollover event. Active safety functions are intended to reduce the likelihood of an impact, and include such features as blind spot detection, adaptive cruise control and other advanced driver assist systems (ADAS). Some technologies are enabled through the use of vehicle interior-mounted displays and cameras. An interior camera oriented toward the driver can be used for communication functions and can also monitor driver alertness and their position relative to the vehicle steering wheel and other structures. One location for mounting these devices is on the upper surface of a vehicle steering column. There are numerous challenges posed by providing such a mounting location. Steering columns are designed with crushable structures to absorbed impact energy upon a frontal impact. Typically a driver airbag is carried by the vehicle steering wheel and inflates to absorb impact energy. Whether or not a driver airbag inflates, compressive loads are placed on the steering column and its energy absorbing crushable features and enable it to stroke to absorb energy. Any cameras or other device mounted on the upper portion of the steering column need to accommodate such displacement and loading conditions.

[0004] Column mounted camera systems on the steering wheel pose a problem of becoming a hazard in a crash situation. Conventional MHI displays are provided in the vehicle instrument panel. In some applications, it is desirable to provide the display near the upper surface of the steering column. This forward positioning gives access to the driverfor proper HMI input from the driver. Mounting any kind of module such as a camera in front of these displays may have adverse effects in a crash situation, as the packaging in and around the steering wheel is very dense and is sensitive and prone to damage due to mechanical vibration and shock. In a crash situation it is important that components not be free to move in an uncontrolled manner in the vehicle interior which could pose an occupant injury risk. In addition, the devices must not interfere with the proper deployment of an inflatable restraint carried by the steering wheel hub or other mounting positions. Further, it is desirable to protect the sensitive and expensive display components from mechanical damage in an impact or any other condition where a camera might become dislodged from its mounted position in front of the display.

SUMMARY

[0005] In accordance with the present invention a camera module mountable in a vehicle is provided. The camera module includes a camera and a mount. The mount is preferably adapted to be positioned at the upper surface of a vehicle steering column. The camera assembly is affixed to the mount through snap features that are configured to release though cam features during an impact to control the direction of the camera during dislodgement. A tether can be used attached to the camera assembly to further constrain its motion after detachment.

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] Figure 1 is a frontal view of a motor vehicle steering wheel.

[0007] Figure 2 is a side view of a motor vehicle steering wheel and steering column showing locations for mounting a display and camera assembly.

[0008] Figure 3 is a pictorial view of a camera assembly detached from its mounting structure.

[0009] Figure 4 is a pictorial view of the camera assembly affixed to its mounting structure.

[0010] Figure 5 is a pictorial view showing the camera assembly in a mounted position and showing exemplary inertial forces acting on the camera assembly.

[0011] Figure 6 is a side view showing the camera assembly dislodged from the mounting structure.

[0012] Figure 7 is a pictorial view of the camera assembly mounted to the upper portion of a vehicle steering column.

DETAILED DESCRIPTION

[0013] Figure 1 illustrates an example of a motor vehicle steering wheel assembly 10 shown from the perspective of a driver position behind the steering wheel. A small portion of camera assembly 12 can be seen in the upper open quadrant of steering wheel assembly 10.

[0014] Figure 2 is a side view of steering wheel assembly 10 showing steering column 14 and control stalk 16 and the position of display 18, normally integrated into the vehicle’s instrument panel. As shown, there is a close spacing in the fore-and-aft (vehicle forward traveling) direction between camera assembly 12 and display 18. For reasons discussed previously, it is desirable to protect display 18 from damage and otherwise to control the movement of camera assembly 18 should it become dislodged from its mounted position in an impact or other event.

[0015] Figure 3 provides a pictorial view of camera assembly 12. As shown camera assembly 12 includes a generally flat housing base 22 and upwardly extending panel 24 providing a mount for an imaging sensor and associated optical components 26 (not shown in detail). On the bottom surface of panel 24 there is provided four downwardly projecting legs 28 each having lower ramped barbs or teeth 30. Teeth 30 feature a ramped lower surface 32 and a forward projecting barb 34. Housing base 22 features four of teeth 30 with a pair aligned on each lateral side of the base, although other numbers could be provided.

[0016] Figure 4-6 show camera assembly 12 mounted to camera mounting structure 36. Camera mounting structure 36 may be a separately formed component affixed (removably or permanently) to steering column shroud 38 or may have its features integrated into a larger part of shroud 38 (or another component). Mounting structure 36 incorporates rectangularfirst apertures 40 for receiving legs 28 for locking in place camera assembly 12. Referring in particular to Figure 5, legs 28 are received into apertures 40 which are dimensioned to cause deflection of the legs, squeezing them together laterally and then allowing them to snap into a final install position with teeth 30 engaged with a underside surface below apertures 40. In accordance with this invention features are provided for causing the separation between camera assembly 12 and mounting structure 36 to happen in a controlled and predicted manner. For example, inertial forces may act on camera assembly 12 in an impact or other obstacles such as an inflating airbag or other forces may act on camera assembly 12, causing it to become detached from mounting structure 36. [0017] Referring to Figures 5 and 6, mounting structure 36 includes first apertures 40 for receiving legs 28 and second aperture 46 separated from aperture 40. Cavity 48 extends between the two apertures 40 and 46, with tab feature 50 between them. Tab feature 50 provides a weakened area which will fail when loads act on camera assembly 12 as will be described further as follows. In the installed position, leg teeth 30 snap in position with barbs 34 hooked onto a lower surface of mounting structure 36. Mounting structure 36 provides curved ramp (or cam) surfaces 42 creating a curved pathway 44 for movement of legs 28 in the event that loads act on camera assembly 12 causing it to become dislodged. Curved pathway 44 extends between the two apertures and provides a surface for legs 28 to ride along upon the occurrence of camera assembly 12 being released from mounting structure 36. The ramp or cam surfaces 42 may be radiused forward and upward (in the vehicle forward travel direction) to assist and control pivoting of camera module 12 during dislodgment.

[0018] Figure 5 shows camera assembly 12 fastened in position to mounting structure 36. As shown, legs 28 are snapped into position. Figure 5 shows an example colliding structure 54 contacting camera assembly 12. Colliding structure 54 is just an example of any object that might contact or act on camera assembly 12 causing it to become detached. Similar detachment can occur strictly through inertial forces acting on the camera assembly 12. Colliding structure 54 is only exemplary of any force input causing detachment of camera assembly 12.

[0019] As illustrated in Figure 6, when sufficient loads are applied to camera assembly 12, tab feature 50 preferably fails to release the camera assembly. In the event of such detachment, legs 28 riding along ramp surfaces 42 produce an upward displacement of camera assembly 12 as it separates from mounting structure 36. This produces a predictable and controlled trajectory for camera assembly 12 upon its separation. As shown by Figures 3-4 and 7 cable 56 is attached to camera assembly 12 and includes an electrical connector 58. Cable 56 acts as a tether providing a structural connection to restrain motion of camera assembly 12 after release from the mounting structure 36. Preferably, cable 56 has necessary tensile properties with a suitable strong connection with camera assembly 12 and electrical connector 58 which would be attached to an associated vehicle interior component. Routing of cable 56 is shown in a diagrammatic manner in Figure 7. In practice, cable 56 and electrical connector 58 would be enclosed by shroud 38 or other interior panels. The length of the cable 56 is chosen to prevent the fully dislodged camera assembly 12 from entering the airbag deployment zone or from traveling into the instrument display 18. Cable 56 may be attached to the side of camera assembly 12 such that the tension in the cable will direct the camera unit to the side when dislodged. In some implementation, more than one cable or tether may be used.

[0020] It is also contemplated within this disclosure that camera assembly 12 may be replaced by a different attachment unit or electronic unit and that the ramp surfaces 52 may be provided to extend or curve in another manner to direct the unit in a different direction. The weakened areas provided by tab portion 50 may be material within the mounting structure 36 that breaks away as the unit is dislodged. Camera assembly leg barbs 34 may have an edge that may be sharp to cut into or otherwise aid in the breaking away of the weakened areas during dislodgement.

[0021] Further, it is contemplated within this disclosure that the snap features and the ramp or cam features may be located on either the camera assembly or the mounting structure to control the direction of dislodgement of the camera during an impact.

[0022] As a person skilled in the art will readily appreciate, the above description is meant as an illustration of the principles of this application. This description is not intended to limit the scope or application of the claim in that the assembly is susceptible to modification, variation and change, without departing from spirit of this application, as defined in the following claims.