VEHICLE AIR-BAG MINIMUM DISTANCE ENFORCEMENT APPARATUS, METHOD AND SYSTEM
RELATED APPLICATION INFORMATION
This continuation-in-part application claims the benefit of and priority to U.S. Patent Application No. 09/897,536, filed July 2, 2001; U.S. Patent Application No. 09/220,832, filed December 24, 1998; U.S. Provisional Application No. 60/101,487, filed September 23, 1998; U.S. Provisional Application No. 60/105,245, filed October 22, 1998; and U.S. Provisional
Application No. 60/105,595, filed October 26, 1998.
FIELD OF THE INVENTION
The present invention relates to safety systems and methods for vehicles, and, in particular, to vehicle air-bag systems, that take into account a clearance between a vehicle passenger and an air-bag.
BACKGROUND INFORMATION
Although statistics may indicate that vehicles equipped with air-bags have enhanced passenger safety, under certain conditions air-bags may have been identified as a source of passenger injuries and may have even been cited in some cases as causing death. As understood, deaths may have been attributed to air-bags predominantly in low-speed accidents, and air-bags may have also been a factor in deaths resulting from high-speed accidents. Some of these injuries may have involved shorter drivers (especially, for example, drivers about 5' 0" or less in height) who adjust the seat position so that a distance between the air-bag and the driver are reduced below a safe clearance. Drivers taller than about 5' 0" may also position themselves within the minimum safe clearance, and this positioning may be dangerous regardless of the height of the driver, hi certain systems, as all of the adjustment for drivers of various sizes may be done through seat movement, shorter drivers may be positioned closer to the steering wheel (and the air-bag contained therein) than are taller drivers. As indicated above, this may result in shorter drivers (such as, for example, those about 5' 0" or less in height), along with taller drivers who chose to sit close to the steering
wheel, being positioned within a predetermined safe clearance. Depending on the air-bag system used, the safe clearance may vary. It is believed that a clearance of about 10" between the driver and the air-bag should generally be sufficient to eliminate at least certain ones of any negative effects of air-bag systems. Vehicle seats may allow adjustment of the driver's seat between a rearward-most position and a forward-most position separated by a distance sufficient to accommodate the range of leg lengths in the adult population, such as, for example, approximately 8". It is believed that these systems may address differences in leg length, as differences in arm and torso length among the population may be less substantial. Thus, to operate the pedals in prior systems, shorter adults were forced to move the seat forward, often to the forward-most position while a portion of taller adults also chose to move the seat beyond the safe clearance. This causes a corresponding distance closure between the drivers chest and head and the steering wheel in which the air-bag is often located. Thus, when the seat is in the forward-most position, a driver will be separated from the steering wheel by a distance less than the required minimum safe clearance. This problem may have been addressed by systems that determine when the driver is positioned closer than the minimum safe clearance and then adjust or suspend air-bag operation, hi addition to disabling air-bags when the clearance is unsafe, prior systems have slowed the rate of air-bag inflation or inflated the air-bag in stages. These systems, however, may deprive shorter drivers of the full effectiveness of the air-bag system.
Other areas of concern are in the appropriate use of reduced inflation bags and in post- crash escape and rescue actions. Seat belts, automatic door locks and electric windows may become liabilities following severe impact, rollover, or in submerged vehicle situations. It is believed, however, that insufficient attention may have been given to computerized safety automation and post-crash escape as they relate to these features.
Rather, industry efforts have been directed to manual devices such as the "Pointed Window Breaking Hammer" now offered as a car safety accessory to expedite escape.
SUMMARY OF THE INVENTION An exemplary embodiment and/or exemplary method of the present invention is directed to a vehicle safety device including a seat mounted within a passenger compartment
of the vehicle', in which the seat is movably connected to a vehicle frame by a seat position adjusting mechanism which allows the seat to move along an axis between a forward-most position and a rearward-most position. An air-bag is mounted within the passenger compartment in front of the forward-most position of the seat, with the forward-most position of the seat defined as a position of the seat in which a distance between a passenger seated in the seat and the air-bag is equal to a minimum safe clearance.
An exemplary embodiment and/or exemplary method of the present invention is also directed to a method of maintaining a minimum safe clearance between an air-bag mounted in a vehicle and a vehicle passenger including the steps of preventing motion of a seat toward the air-bag beyond a forward-most position wherein, when in the forward-most position, a passenger seated in the seat is separated from the air-bag by a predetermined minimum safe clearance and providing a position adjusting mechanism for at least one vehicle control pedal to allow a passenger seated in the seat to adjust a distance between the seat and the at least one pedal by moving the at least one pedal toward and away from the seat. An exemplary embodiment and/or exemplary method of the present invention is also directed to a vehicle safety device includes a seat mounted within a passenger compartment of the vehicle, in which the seat is movably connected to a vehicle frame by a seat position adjusting mechanism that allows the seat to move along an axis between a forward-most position and a rearward-most position. An air-bag is mounted within the passenger compartment in front of the forward-most position of the seat, with the forward-most position of the seat defined as a position of the seat in which a distance between a passenger seated in the seat and the air-bag is equal to a minimum safe clearance. In addition, an exemplary method of maintaining a minimum safe clearance between an air-bag mounted in a vehicle and a vehicle passenger includes the steps of preventing motion of a seat toward the air-bag beyond a forward-most position, in which, when in the forward-most position, a passenger seated in the seat is separated from the air-bag by a predetermined minimum safe clearance, and providing a position adjusting mechanism for at least one vehicle control pedal to allow a passenger seated in the seat to adjust a distance between the seat and the at least one pedal by moving the at least one pedal toward and away from the seat. An automatic seat positioning system, which takes into account both seat to air-bag distance and eye height and automatically, may be used to optimally position a passenger to maximize safety and comfort.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 A shows a driver side view of a passenger compartment of a vehicle equipped with a vehicle safety system according to a first exemplary embodiment of the present invention. Figure 1 B shows a passenger side view of a passenger compartment of a vehicle equipped with a vehicle safety system according to a first exemplary embodiment of the present invention.
Figure 2 shows a partially cross-sectional side view of a first pedal position adjustment apparatus for use with the first embodiment of the invention. Figure 3 shows a partially cross-sectional side view of a second pedal position adjustment apparatus for use with the first embodiment of the invention.
Figure 4A shows a partially cross-sectional front view of the pedal position adjustment apparatus of Figure 3.
Figure 4B shows a partially cross-sectional front view of the pedal position adjustment apparatus of Figure 3, including the motor and worm gear arrangement.
Figure 5 shows a partially cross-sectional side view of a third pedal position adjustment apparatus for use with the first embodiment of the invention.
Figure 6 shows a plan diagram of a computer controlled vehicle safety system according to the exemplary embodiment and/or exemplary method of the present invention; Figure 7A shows a partially cross-sectional side view of a fourth pedal position adjustment apparatus for use with the first exemplary embodiment of the present invention.
Figure 7B shows a partially cross-sectional side view of another exemplary fourth pedal position adjustment apparatus for use with the first exemplary embodiment of the present invention. Figure 8 shows a cross-sectional view of the pedal position adjustment 20 mechanism of Figure 7 A and or Figure 7B taken on a plane perpendicular to that of Figure 7A andor Figure 7B.
Figure 9 shows a side view of an exemplary motor and worm gear arrangement that may be used with the exemplary embodiments of Figures 2, 3, 5 and 6. Figure 10A shows the path of a lap belt and a shoulder belt with respect to a vehicle seat.
Figure 1 OB shows an extended view of a path of a lap or shoulder belt for use in determining a protrusion amount or a depth of a person seated in the vehicle seat.
Figure 11 shows a method or program #7 for providing automatic driver positioning using the methods or programs of Figures 12C to 12F. Figure 12A shows a method (program #1) for moving a vehicle seat forward based on a person using the operator controlled seat slide switch or controller arrangement.
Figure 12B shows a method (program #2) for moving a vehicle seat rearward based on a person using the operator controlled seat slide switch or controller arrangement.
Figure 12C shows a method (program #3) for moving a vehicle seat forward based on using automatic action or control of a seat slide switch or controller arrangement.
Figure 12D shows a method (program #4) for moving a vehicle seat rearward based on using automatic action or control of the seat slide switch or controller arrangement.
Figure 12E shows a method (program #5) for moving a vehicle seat upward based on manual action/control or automatic action/control of the seat vertical movement switch or controller arrangement.
Figure 12F shows a method (program #6) for moving a vehicle seat downward based on manual action/control or automatic action/control of the seat vertical movement switch or controller arrangement.
DETAILED DESCRIPTION
Figure 1 A shows a system according to an exemplary embodiment of the present invention in which a driver positioned on a seat 2 adjusts the position of the seat 2 to a desired position between rearward and forward-most positions separated by a distance X. Then, the driver adjusts the position of the pedals 4 so that, when in the desired seat position, the driver can comfortably reach the pedals 4 (accelerator, brake, clutch, etc.). Any suitably appropriate manual or automatic seat positioning mechanism may be employed in a vehicle safety device according to the exemplary embodiment and/or exemplary method of the present invention. For example, a seat position adjusting mechanism may include a lever 11 which, in a first position, prevents the seat 2 from moving forward and rearward and which, in a second position, releases the seat 2 so that the seat 2 may be moved forward and rearward by a passenger seated in the seat 2.
A ve cle safety system according to the exemplary embodiment of the present invention limits the motion of the seat 2 toward the steering wheel 6 or other point of deployment of an air-bag 8 so that a distance A between the driver and the air-bag 8 is at least a minimum safe clearance. Thereafter, the remainder of any further reduction of the distance between the driver and the pedals 4 is achieved by a rearward adjustment of the position of the foot pedals 4.
By providing limited adjustment of the position of the seat 2, drivers may still adjust for the relatively smaller variations in chest depth and arm length while the adjustment of the position of the pedals 4 allows for the larger adjustments necessary to accommodate differences in leg length.
The minimum safe clearance may be maintained by limiting seat-back motion toward the steering wheel 6 center to a distance equal to the minimum safe clearance plus a value for a minimum adult chest depth (such as, for example, approximately 8"). Thus, for a 10" minimum safe clearance and using 8" for the minimum adult chest depth, the seat 2 would be prevented from moving forward past a point where the seat-back is 18" from the steering wheel 6. In such a system, as pedal position adjustment allows for the greater difference in leg length, a distance between the forward-most and rearward-most positions of the seat, allowing only for the lesser differences between chest depth and arm length, could be reduced to approximately 21/2". Then, providing 6" of adjustment between forward-most and rearward-most positions of the foot pedals 4 makes available to the driver of such a vehicle an amount of total adjustment of the distance between the driver and the pedals 4 comparable to that provided in previous systems. Although distances between the driver and the steering wheel 6 are being discussed as examples, the only distance that matters is that between an occupant of the vehicle (driver or passenger) and the air-bag cover, which is a distance A from the steering wheel located air-bag for the driver of Fig. 1 A and which is a distance A' from the dashboard located air-bag for the passenger of Fig. IB.
Figure 2 shows a manual system for pedal position adjustment which operates similarly to the mechanisms in use for manual adjustment of seat position. When a lever 12 is moved into a release position, a pedal slide mechanism 14 coupled between the frame of the vehicle 1 and the pedals 4 is released into an unlocked configuration in which a pedal slide housing 18 and, consequently, the pedals 4 may be slid forward and rearward relative to
the vehicle dashboard 16 (Figure 1) to a desired position. When the lever 12 is moved from the release position to a locked position, the pedal slide housing 18 is locked into the desired position. Of course, the lever 12 may be biased toward the locked position, such as, for example, by a spring, so that the lever 12 automatically returns to the locked position when released. If desired, individual pedals 4 may be mounted to separate pedal slide mechanisms
14 thereby allowing each pedal 4 to be adjusted to an optimum position. Alternatively, the pedals 4 may be coupled together for motion forward and rearward in unison so that a predetermined relative positioning of the pedals 4 is maintained.
The pedal 4 of Figure 2 is pivotally coupled to a slide housing 18 for rotation about an axle 20 with an upper extension 24 of the pedal bar 22. The upper extension 24 abuts a first pin 26 which is slidably received in a channel 28 formed in the slide housing 18 and a first pulley 30 is pivotally mounted on the first pin 26. A second pulley 32 is pivotally mounted on a second pin 34 which is fixedly coupled to the slide housing 18 and a cable 36 extends from an anchor 38, around the first and second pulleys 30, 32, through a firewall 40 via a conduit 41 to an actuator 98a which operates a vehicle control device 99, such as, for example, clutch, brake or accelerator.
The letter P in Figure 2 indicates the position of the pedal 4 in a pressed position while the letter U indicates the position of the pedal 4 in an unpressed position. When in the unpressed position U, the upper extension 24 extends substantially vertically so that the first pin 26 and the first pulley 30 are positioned at the front of the channel 28 as the pedal 4 is biased into the unpressed position U by, for example, a spring or other known mechanism. In the unpressed position U with the first pulley 30 at the front of the channel 28, a portion of the cable 36 extending between the anchor 38 and the first pulley 30 is at a minimum length thereby operating the actuator into a configuration corresponding to the unpressed condition of the pedal 4. When the pedal 4 is depressed to the pressed position P, the upper extension
24 rotates (clockwise as seen in Figure 2) to the position indicated by the dashed line pushing the first pin 26 and the first pulley 30 rearward in the channel 28 and increasing the length of the portion of the cable 36 which extends between the first pulley 30 and the anchor 38. This draws the actuator into a configuration corresponding to the pressed position P of the pedal 4. The slide housing 18 is slidably mounted to a channel member 42 which is rigidly coupled to a lower surface of the dashboard 16 or bracketed to the firewall 40 for motion
between forward-most and rearward-most pedal positions separated by a distance B. Regardless of the position of the slide housing 18 along the channel member 42, the total cable length from the firewall 40 to anchor 38 remains constant and, therefore, the action of the cable 36 on the actuator will be unchanged by an adjustment of the position of the slide housing 18. Thus, the position of the pedal 4 may be adjusted forward and rearward without affecting the operation of the actuator or the corresponding vehicle control device.
Figure 3 shows an adjustable pedal position mechanism substantially similar to that of Figure 2 except that the slide housing 18 extends further vertically with the first pulley 30 arranged below the second pulley 32 as opposed to the lateral arrangement depicted in Figure 2 and, in addition, Figure 3 shows a mechanism for locking the pedal slide mechanism 14 in a desired position. In addition, Figure 3 shows an exemplary mechanism for locking the slide housing 18 and, consequently, the pedal 4 in a desired position along the channel member 42. The locking mechanism includes a ridged plate 44 biased toward an upper surface of the slide housing 18 by springs 46. The ridged plate 44 includes a plurality of projections 48 sized to be received in recesses 50 formed in an upper surface of the slide housing 18. The ridged plate 44 is coupled to the lever 12 so that, when the lever 12 is pulled upward, the ridged plate 44 is disengaged from the slide housing 18 and the slide housing 18 may be freely slid forwardly and rearwardly along the channel 42. Then, when the lever 12 is released after adjusting the pedal 4 to the desired position, springs 46 move the ridged plate 44 down into engagement with the recesses 50 of the slide housing 18 to maintain the slide housing 18 in the desired position. The above-described locking mechanism is exemplary only and that any number of known mechanisms may be used to lock the channel in the desired position.
Figure 4 A shows a partially cross-sectional front view of the adjustable pedal position mechanism of Figure 3 showing two pedals 4 mounted to slide housings 18 which are rigidly coupled to one another via a connecting member 52 so that the position of both pedals 4 relative to one another is maintained constant as the adjustable pedal position mechanism is operated to achieve a desired pedal position. As indicated by the third pedal 4 shown in dotted lines in Figure 4A, any number of pedals may be interlinked for common forward and rearward motion with this mechanism. In the alternative, additional pedals may be de-linked from the first two pedals to allow independent positioning thereof. In addition, one or more slide housings 18 may be formed as a single one-piece unit together with the corresponding
connecting members 52 so that the unit as a whole moves along the channel 42.
Figure 5 shows an alternative embodiment of the adjustable pedal position mechanism of Figure 2 which incorporates structure essentially identical to that of Figure 2 except that the cable 36 is coupled at one end to the anchor 38 while the other end of the cable 36 is coupled to a lever 54 which is pivotally coupled to the fire wall 40 via a mount 56. The lever
54 is positioned adjacent a member 58 which, when depressed, may operate either an electric switch sending a signal corresponding to a degree of depression of the pedal 4 to the vehicle control device via the actuator 98a which actuates a vehicle control device as is known in the art. In addition, the adjustable pedal position mechanism of Figure 5 is coupled, for example, via the motor and worm gear arrangement 61 of Figure 9, which includes the worm gear arrangement 63 having a gear 63 a and a gear shaft 63b, and the servo motor 62 for automatically adjusting the position of the pedal 4. The motor and worm gear arrangement 61 of Figure 9 may also, for example, be used with the exemplary embodiments of Figures 2, 3 and 6. Specifically, the servo motor 62 operates based on input from the driver to move the pedal 4 forward or rearward to the desired position and to lock the pedal 4 in the desired position. Alternatively, the servo motor may be operated based on memory stored in a CPU of a vehicle control system to select a predetermined pedal position (or pedal and seat position) based on predetermined preferences for the current driver. Of course, for such systems with the pedal position adjusted in accord with commands from a CPU, the seat position and pedal position may be automatically controlled in accord with criteria stored in a memory to ensure that the minimum safe clearance is maintained.
As a substitute for the servo motor 62 of Figure 5, any suitable automatically operable power source may be employed to automatically adjust the position of the pedals 4 employing any number of suitable mechanisms such as those employed, for example, with powered seats.
As shown in Figure 6, an adjustable pedal position mechanism as in Figure 5, may be integrated into a computerized vehicle safety system operated by a processor arrangement 64, which may be a microprocessor arrangement, an ASIC processor arrangement or any other suitably appropriate processor arrangement, which is used to monitor and/or control various vehicle functions, as well as vehicle conditions, external conditions (including road and environmental conditions), operating information and/or status information.
The processor arrangement 64 is coupled to a multiplicity of vehicle control devices including, for example, a clutch control 66, a brake control 68, a throttle control 70, operating condition sensors including, for example, speed and direction sensors 72 and exterior distance sensors 74. In addition, the processor arrangement 64 is coupled to vehicle safety components including, for example, driver notification devices 76; crash sensitive in-car device controls 78 which may, for example, control door and seat belt unlocking, window opening, motor shut-off, placement of 911 calls; and an air-bag inflation control system 80; and sensors supplying information to the vehicle safety system including, for example, a child seat detector 82, a seat occupied sensor 84, a seat belt in use sensor 86, driver/passenger distance and elevation sensors 88, 98, seat position sensors 90 and submerged vehicle condition sensors 92. The processor arrangement may also be coupled to a vehicle steering wheel position arrangement (or sensor system) 170, for use in determining the position of a telescoping vehicle steering wheel for use in determining the minimum clearance distance between an air-bag and a driver. The occurrence of a crash may be detected, for example, by the acceleration or other sensors used to activate the air-bags, roll-over sensors, etc.
In particular, a collision or crash detection arrangement or system 150 (which may be any suitably appropriate arrangement) may also be communicatively or operatively coupled to the processor arrangement or system 64, which may then operate to control various vehicle control arrangements and/or systems so as to configure or set them to appropriate post- collision configurations or settings. In particular, the processor arrangement 64, based on the collision information from the collision detection arrangement 150, may operate to control the following vehicle systems: vehicle engine control arrangement or system 152 to shut down the engine; vehicle door locking control arrangement or system 154 to unlock the vehicle door(s); vehicle power window control arrangement or system 156 to raise or lower the vehicle window(s); and vehicle communication arrangement or system 158 to request assistance using a suitably appropriate communication system, such as, for example, a cellular communication system (which may be, for example, the Tele- Aid™ system (from Daimler-Benz Corporation) or the OnStar™ system (from General Motors Corporation). An alternative pedal position adjustment mechanism of Figure 6 is substantially identical to the pedal position adjustment apparatus described in the previous embodiments except that instead of the cable coupled to an actuator via a first fixed pulley and a second
movable pulfey, a sensor 94 detects a degree of rotation of each of the pedals 4 about the axle 20. Each sensor 94 supplies an output signal corresponding to the angular position of the corresponding pedal 4 to the processor arrangement 64 which supplies a corresponding control signal to a vehicle control device corresponding to the particular pedal 4. The computerized vehicle safety system of Figure 6 may allow adjustment of both seat and pedal position through operation of a single switch 95 corresponding to currently employed seat position switches, but may be pre-pro rammed to prevent the driver from adjusting the seat to a position within the minimum safe clearance. As the driver operates the switch 95 to request a forward motion of the seat 2, the processor arrangement 64 operates the servo motor to direct a forward motion of the seat 2 until the driver reaches the minimum safe clearance (as determined by either a driver position sensor or a pre-set forward-most seat position). The processor arrangement 64 then halts the forward motion of the seat 2 locking the seat 2 in the forward-most position and begins moving the pedals 4 toward the driver until the driver indicates that a desired position of the pedals 4 has been achieved. The processor arrangement 64 then directs the adjustable pedal position mechanism to lock the pedals 4 in the desired position. Alternatively, the system of Figure 6 may also include a separate pedal position switch 97 allowing the passenger to adjust the position of the pedals 4 regardless of the current position of the seat 2.
Even in view of the minimal travel and limited use of motorized telescopic steering wheels, such a system may be interfaced to the processor arrangement 64 to retract as necessary, prior to advancing the pedals towards the driver.
As described above, an exemplary embodiment of the present invention may use, as an alternative to a predetermined forward-most seat position based on a minimum adult chest depth, an electronic passenger distance sensor 88 to monitor, such as, for example, chest to air-bag distance. The processor arrangement 64 then monitors the chest to air-bag distance and controls motion of the seat 2 and the pedals 4 to maintain the minimum safe clearance. Upon detecting the minimum safe distance has been achieved, forward seat motion is halted and all further motion request of the driver is transferred to the servo motor 62. In addition, although the seat is prevented from moving forward beyond the minimum safe clearance, if a driver or passenger moves his body relative to the seat to temporarily encroach beyond the minimum safe clearance, the processor arrangement 64 may control the air-bag inflation
control 80 to cause it to operate in a reduced clearance mode in which, under predetermined conditions, the system may, for example, reduce an inflation pressure, disable the air-bag or deploy the air-bag in staged inflation until the driver or passenger returns beyond the minimum safe clearance. When the driver has returned beyond the minimum safe clearance, the system discontinues the reduced clearance mode operation.
Upon an adjustment for rear movement of the seat 2 being called for, the processor arrangement 64 directs operation in reverse of that employed for forward motion of the seat 2. That is, when the servo motor 62 is operated to retract the pedals 4 (toward the front of the vehicle), until the forward-most position of the pedals 4 is reached. Then processor arrangement 64 directs additional distance adjustments by moving the seat 2 rearward.
An optional front limit button 96 permits a driver to select as a personal forward-most position, any position of the seat 2 in which the passenger seated therein is separated from the air-bag by at least the minimum safe clearance and to make adjustments for leg length by moving the pedals 4 rearward. This allows drivers of all sizes to take advantage of a more rearward pedal position thereby reducing the possibility of lower limb injury.
The present design of "seat slide only" adjustment has also resulted in visual limitations to drivers of small stature as shorter drivers stretch to reach the pedals 4. This need to stretch in turn limits the amount of seat elevation that can be physically used.
It is believed, however, that rearward adjustment of the position of the pedals 4 offered by the exemplary embodiment of the present invention may eliminate such stretching, and may allow a full range of seat elevation to be employed by all drivers regardless of height, permitting all to obtain optimum design eye level.
An elevation sensor 98 may be coupled to the processor arrangement 64 positioned within the passenger compartment to detect an actual height of a driver's head. The elevation sensor 98 may employ technology such as ultrasonic sensors similar to sensors included in commercially available distance meters. Using a standard value representing an average difference between a height of the top of a person's head and their eyes, (such as, for example, 4") an optimum eye elevation position may be automatically obtained as the processor arrangement 64 directs an electric motor (not shown) in the seat 2 to elevate the seat 2 until the elevation sensor 98 indicates that the optimum eye level has been obtained. As shown in Figures 1 A and IB, a distance NN1 from the sensor 98 (roof position) to a
corresponding to 4 inches below a top of the head is believed to correspond to an optimal or at least a good distance NN2 of the sensor 98 with respect to the top of the head.
Thus, the exemplary embodiment of the present invention provides an automatic driver seat positioning system (DPS), which uses both front and elevation sensors to automatically position the driver in an optimum visual and air-bag protection position.
Although the described exemplary embodiments show overhead or dashboard slung foot pedals and a pedal position adjustment mechanism adapted thereto, the exemplary embodiments and/or exemplary methods of the present invention may also be applied in vehicles with floor mounted pedals or other pedal mounting arrangements, so long as a combination of pedal movement and seat movement is provided to ensure that a minimum safe clearance between the driver or other passenger and an air-bag is maintained. In addition, though the described embodiments and examples refer to driver seat control and a steering wheel located air-bag, the same concepts may be applied to other passenger seating and air-bag arrangements to maintain a minimum safe clearance between the passenger and the air-bag.
As indicated in Figure 6, the processor arrangement 64 may be coupled to a plurality of vehicle systems to create an integrated vehicle safety system. Specifically, in addition to controlling the air-bag system and the seat and pedals to maintain a minimum safe clearance, the system of Figure 6 may include, for example, sensors for determining whether a child seat is mounted on a particular seat, whether a particular seat belt is in use, the position of the seats, whether a vehicle is submerged or in another post-crash situation and systems for disabling the ignition of the vehicle after an accident, for automatically lowering the windows in a submerged vehicle situation, for unlocking the doors and unfastening the seat belts after an accident and for operating a cell phone and/or navigation system to make a call to 911. The driver/passenger distance sensors 88 offer a practical method of controlling the inflation of multi stage and or controlled inflation air-bags, when so equipped. Thus, for example, when the distance sensor 88 indicates that the minimum safe distance has been encroached upon, the corresponding air-bag would be activated at a reduced inflation rate. An optimum air-bag inflation activation and rate may be continuously computed by the processor arrangement 64 based upon input from sensors 72, 74, 82, 84, 86 and 88.
For example, encroachment beyond the minimum safe clearance, or the detection of a
low speed impact, based upon exterior distance sensors 74 and vehicle speed, would initiate a lower inflation setting for the related air-bag. Thus, the system is further enhanced by interfacing with other systems that detect seat occupancy and/or active seat belt use, providing a continuous basis of multi-factor safe inflation evaluation. It is'believed that present foot pedal designs may vary considerably by auto manufacturer, and may therefore use cable control or rod control of gas, brake and clutch. In the exemplary embodiment, all of the foot pedals may be mounted on a single sliding platform located under dash, supported from the firewall and/or dash, and activated by either manual or motorized control as described above. Combined with motorized control, the vehicle safety system of Figure 6 may employ the sensors 98 and 88 to provide automatic, optimized driver positioning, regardless of weight or height.
This customized driver positioning system may be implemented by the processor arrangement 64 by, for example, activating seat/pedal position control in the following 3 steps: (1) The seat 2 is first returned to its lowest and rearward-most position; (2) After step 1 has been achieved, the seat 2 is then elevated to its optimum eye level position, that is, the point at which the distance indicated by elevation sensor 98 equals an optimum distance stored in memory; and (3) After steps 1 and step 2 have been completed, the seat 2 is advanced to its minimum safe position, the point at which the distance indicated by the distance sensor 88 is equal to a predetermined minimum safe distance stored in memory or, alternatively, by advancing the seat 2 to a preselected forward-most position.
These steps may be performed in any order. By adjusting the eye height first, however, this should eliminate or at least reduce inaccuracies in detecting the distance between the passenger and the air-bag that may result from the varying contour of the passenger (that is, some portions of the passengers anatomy may project further forward than others). Thus, if horizontal positioning is performed first, a later change in vertical position may alter the critical distance between the sensed portion of the passenger and the air-bag.
The driver would then adjust the pedals 4 to the most comfortable position by further activating the seat position activator. Figures 7 A, 7B and 8 show an alternative adjustable pedal position mechanism which eliminates the cable and pulley arrangements of Figures 2 and 3. Specifically, the adjustable
pedal position mechanism of Figures 7A, 7B and 8 includes geared slides 100, 102 mounted on rollers 104 and mounted within a housing 106. The geared slides 100, 102 are maintained in position within the housing 106 by guides 108 with a circular gear 110 mounted therebetween. The circular gear 110 is non-rotatably coupled to the pedal rod 22 which extends into the housing 106 via an opening 107 and, consequently, to the pedal 4 by a pin
112 which rides in slots or channels 28a formed in opposed walls of the housing 106. The circular gear 110 is held in an engaged position between the geared slides 100,102 in which teeth of the circular gear 110 engage teeth of the slides 100, 102 by the bias of a spring 114 which abuts a knob 116 which extends out of the housing 106. The knob 116 is mounted on the pin 112 so that, when the knob 116 is pushed toward the housing 106 against the bias of spring 114, the circular gear 110 is moved to a disengaged position in which the teeth of the circular gear are out of engagement with the teeth of the slides 100,102.
Thus, by depressing the knob 116, the circular gear 110 and the pedal 4 can be slid to any position along the length of housing 106. Upon releasing the knob 116, the teeth of the circular gear 110 again engages the teeth of slides 100, 102 and the pedal 4 is locked in a new position. When the pedal 4 is depressed, the pedal rod 22 rotates the circular gear 110 (clockwise as seen in Figures 7A and 7B) which can cause either the slide 100 to slide forward (to the left in Figure 7B) or the slide 102 to slide rearward (to the right in Figure 7B) depending on which of stops 121 and 123 has been removed. In particular, as shown in the appropriate Figures, stop 123 is removed for the cable pull arrangement of Figure 7A, and stop 121 is removed for the push rod arrangement of Figure 7B. The force applied by the pedal 4 to the slides 100, 102 may be applied by the slide 100 to a push rod connector 118, as in Figure 7B, or by the slide 102 to a pull cable 120, as in Figure 7A, and that this force may then be transmitted to an actuator for a corresponding vehicle control device. One of removable stops 121, 123 is thus used at the respective corner 122, 124 to allow either pull cable or push rod control action selection. For example, removal of stop 121 directs all pedal motion to a forward motion of slide 100 using a rod connector 118 while removal of stop 123 directs all pedal motion to a rearward motion of slide 102 which uses a cable connector 120. As with the exemplary embodiments described above, although manual adjustment has been described in regard to the adjustable pedal position mechanism of Figures 7A, 7B
and 8, motonzed control would provide similar action and could be implemented with similar structure. In addition, the exemplary embodiment of the present invention is compatible with any alternative mechanisms for using pedal motion to operate a vehicle control device (such as, for example, hydraulic systems). While a separate motor may be used for the foot pedal track, it could also be accomplished by direct connection to the seat drive, such as in a cable shaft drive common to speedometers. While overhead slung pedals are shown, floor mounted pedals are intended to have similar controls.
Similar seat and distance sensors are suggested for other air-bag protected passengers, to maintain a safe air-bag distance. These distance detectors could be set to halt forward seat movement and issue an audible and/or visible warning when the minimum safe distance is encroached upon.
In addition, braking and accelerator controls may be further monitored and acted upon by the processor arrangement 64 based upon input from the Exterior Distance Sensors 74 in conjunction with Speed and Direction Sensors 72. For example, if the Speed and Direction sensors 72 and related Exterior Distance Sensors 74 detect imminent impact, additional braking forces may be activated via brake control 68.
All safety threats detected by the processor arrangement 64 may also be conveyed to the driver by an audio and/or visual alert system. The processor arrangement 64 is operable to perform a method or program for providing automatic driver positioning, instead of the operator controlled operation of the vehicle seat positioning control arrangement (as shown with Program #1 of Figure 12A and Program #2 of Figure 12B. In particular, Figure 11 shows a method or program 300, namely Program # 7: Automatic Driver Positioning Processor (CPU) Logic. In step 310, the program is initiated or is started. Next, in step 330, the processor arrangement 64 initiates operation of a sub-method or sub-program, namely Program #4 of Figure 12D, in which the vehicle seat is moved rearward to its rearward position limit. Next, in step 350, the processor arrangement 64 initiates operation of a sub-method or sub-program, namely Program #6 of Figure 12F, in which the seat is lowered to its lowest position limit. Next, in step 370, the processor arrangement 64 initiates operation of a sub-method or subprogram, namely Program #5 of Figure 12E, in which a raising movement of a vehicle seat is
limited depending on whether the sensed or determined distance between the interior vehicle roof-liner and the head of an occupant is less than, equal to or greater than the head elevation distance NN2, where NN2 may again be the known vertical distance NN1 (a vertical distance from the interior vehicle roof-liner to a centerline of windshield glass) less a distance of about 4". By initiating Program #5, the processor arrangement 64 may be used to raise the vehicle seat to provide an optimum or at least improved eye elevation). Next, in step 390, the processor arrangement 64 initiates operation of a sub-method or sub-program, namely Program #3 of Figure 12C, in which forward movement of a vehicle seat is limited depending on whether the sensed or determined distance between the air-bag and an occupant is less than, equal to or greater than a minimum enforceable distance, which may be about 10".
Finally, the processor arrangement 64 performs step 395 in which program operation is ended or stopped.
If automatic driver positioning is not being used and if the operator is controlling forward motion of the vehicle seat in block 410 (if not, the program is stopped in block 420), the processor arrangement 64 performs Program #1 (400) of Figure 12A. In this case, if in blocks 430 and 440 the sensed or determined distance (based on inputs from distance sensor 88, seat belt position sensor 190 and/or seat position sensor 90) is greater than some minimum distance or setting (which may be about 10"), the processor arrangement 64 operates to enable operation of the seat advancing or forward positioning motor in block 445. This may be done, for example, by enabling the supply of power to the seat advancing or forward positioning motor in block 445. If in block 450 the sensed or determined distance is equal to or about the same as the minimum distance or setting (which may be about 10"), the processor arrangement 64 operates to enable operation of the pedal advancing or forward positioning motor 62 in block 455. This may be done, for example, by enabling the supply of power to the pedal advancing or forward positioning motor 62 in block 455. If in block 460 the sensed or determined distance is less than some minimum distance or setting (which may be about 10"), the processor arrangement 64 operates to enable operation of the seat retracting or rearward positioning motor in block 465. This may be done, for example, by enabling the supply of power to the seat retracting or rearward positioning motor in block 465. If automatic driver positioning is not being used and if the operator is controlling rearward motion of the vehicle seat in block 510 (if not, the program is stopped in block 520),
the processor arrangement 64 performs Program #2 (500) of Figure 12B. In this case, if in blocks 550 and 540 the sensed or determined distance (based on inputs from distance sensor 88, seat belt position sensor 190 and/or seat position sensor 90) is greater than some minimum distance or setting (which may be about 10"), the processor arrangement 64 operates to enable operation of pedal retracting motor 62 to its limit in block 546, after which the seat retracting or rearward positioning motor may be operated (if the system determines the pedal is at its limit in block 545) to its limit in block 565. This may be done, for example, by enabling the supply of power to the pedal retracting motor 62 in block 546, and thereafter to the seat retracting or rearward positioning motor in block 565. If in block 550 the sensed or determined distance is equal to or about the same as the minimum distance or setting
(which may be about 10"), the processor arrangement 64 operates to enable operation of the seat retract or rearward positioning motor in block 565 if pedal retreat is at its limit in block 545. This may be done, for example, by enabling the supply of power to the seat retracting or rearward positioning motor in block 565, or by enabling the supply of power to the pedal retreat motor in block 546 if pedal retreat is not at its limit in block 545. If the sensed or determined distance is less than some minimum distance or setting (which maybe about 10"), the processor arrangement 64 operates to enable operation of the seat retracting or rearward positioning motor in block 565. This may be done, for example, by enabling the supply of power to the seat retracting or rearward positioning motor in block 565. As described, in step 330, the processor arrangement 64 initiates operation of a sub- method or sub-program, namely Program #4 (700) of Figure 12D, so that if automatic driver positioning is being used and if the operator is not controlling rearward motion of the vehicle seat in block 710, the processor arrangement 64 performs Program #4 of Figure 12D. In this case, the processor arrangement 64 operates to enable operation of pedal retracting motor 62 to its limit in blocks 720 and 730, after which the seat retracting or rearward positioning motor may be operated to its limit in blocks 740 and 750. This may be done, for example, by enabling the supply of power to the pedal retracting motor 62 in block 730, and thereafter to the seat retracting or rearward positioning motor in block 750.
As described, in step 350, the processor arrangement 64 initiates operation of a sub- method or sub-program, namely Program #6 (900) of Figure 12F, in which the vehicle seat is lowered to its lowest position. In block 910, the processor arrangement (or CPU logic) is
initiated by automatic sequence. In block 920, the system determines if the vehicle seat is at its lowest position limit. If the seat is at its lowest position limit, the program is stopped in block 930. If not, the power seat elevation motor is operated to lower the vehicle seat in block 940. As described, in step 370, the processor arrangement 64 initiates operation of a sub- method or sub-program, namely Program #5 (800) of Figure 12E, in which a raising movement of a vehicle seat is limited depending on whether the sensed or determined distance between the interior vehicle roof-liner and the head of an occupant is less than, equal to or greater than the head elevation distance NN2, where NN2 may again be the known vertical distance NNl (a vertical distance from the interior vehicle roof-liner to a centerline of windshield glass) less a distance of about 4". By initiating Program #5, the processor arrangement 64 may be used to raise the vehicle seat to provide an optimum or at least improved eye elevation) in block 810. In particular, if in block 820 the sensed elevation distance is greater than the head elevation distance NN2 in block 830, the processor arrangement 64 operates to cause the vehicle seat positioning arrangement to raise or increase the height of the vehicle seat in block 850. When the distance is equal to or about the same as the head elevation distance NN2 in block 840, the processor arrangement 64 operates to cause the vehicle seat positioning arrangement to stop and hold its position in block 845. If the distance is less than the head elevation distance NN2 in block 846, the processor arrangement 64 operates to cause the vehicle seat positioning arrangement to lower or decrease the height of the vehicle seat in block 847 unless it has been lowered to its limit in block 848. This logic or method of Figure 12E may be initiated by the method or program of Figure 11 , but may also be initiated by the operator.
As described, in step 390, the processor arrangement 64 initiates operation of a sub- method or sub-program, namely Program #3 (600) of Figure 12C, so that if automatic driver positioning is being used and if the operator is not controlling forward motion of the vehicle seat, the processor arrangement 64 performs Program #3 (600) of Figure 12C, beginning at block 61 . In this case, if in blocks 630 and 640 the sensed or determined distance (based on the information from distance sensor 88, seat belt position sensor 190 and/or seat position sensor 90) is greater than some minimum distance or setting (which may be about 10"), the processor arrangement 64 operates to enable operation of the seat advancing or forward
positioning motor in block 645. This may be done, for example, by enabling the supply of power to the seat advancing or forward positioning motor in block 645. If the sensed or determined distance is equal to or about the same as the minimum distance or setting (which maybe about 10") in block 650, the processor arrangement 64 operates to disable operation of the seat advancing or forward positioning motor, to stop advancement of the vehicle seat in block 620. This may be done, for example, by disabling the supply of power to the seat advancing or forward positioning motor in block 620. If the sensed or determined distance is less than some minimum distance or setting (which may be about 10") in block 660, the processor arrangement 64 operates to enable operation of the seat retracting or rearward positioning motor in block 667 (if the vehicle seat is not retracted to its limit in block 665).
This may be done, for example, by enabling the supply of power to the seat retracting or rearward positioning motor in block 667.
As an alternate to the electronic distance sensor described above, the seat belt extraction system described herein may also be used to determine and maintain the safe distance between air bag and driver.
As described above, a minimum distance between an air-bag and a seated person may be about 1 ", and where the body of the person protrudes about 8" with respect to the seat, this means the distance between the air-bag and the seat-back must be at least about 18". Since body shapes may vary, so will the effective protrusion of a person. Thus, the protrusion may be, for example, about 7", 8", 10" or more. The processor arrangement 64 may be used to determine a specific protrusion estimate for a person, to take into account or consider the varying effective minimum distance between an air-bag and a seat-back, so as to maintain the effective or net minimum distance of about 10" between the air-bag and a person. The processor arrangement 64 may use this information to control movement of the seat using the horizontal and vertical seat position control system 180, as shown in Figures 6 and 10A, and or the driver/passenger distance sensor 88 (as shown in Figure 6).
In particular, a seat belt position arrangement or sensor system 190 may be used to provide seat belt length use information for a particular person to the processor arrangement 64. The processor arrangement 64 may then use this information to determine the effective protrusion or depth with respect to the seat-back (that is, the protrusion estimate), rather than a predetermined or fixed protrusion estimate. Using the information from the seat position
sensors 90 and either the estimated protrusion (or the predetermined protrusion if, for example, there is a fault in the system), as well as the vehicle steering wheel position arrangement or system 170 (if there is a telescoping and/or tilting steering wheel), the processor arrangement 64 may be used to control or limit operation of the seat position control system 180, as well as the telescoping and/or tilting steering wheel 88 (prior to advancing the pedals towards the driver).
The processor arrangement 64 may be used to determine the protrusion estimate using a seat belt extraction length based on the information from the seat belt position arrangement or sensor system 190 (to estimate safe distance positioning of a vehicle occupant). As explained, the protrusion of the chest or body of a person may vary from on the order of about
8" to 1 1" or more. The following describes a method for establishing a protrusion table or for using "protrusion" equations, so that the processor arrangement may, in either case, directly estimate an estimated protrusion (and therefore a minimum distance seating position (accounting for seat slide/position and/or steering wheel position for a telescoping and/or tilting steering wheel)) based on an extracted length of seat belt.
Using the relationship of intersecting chords, in which the products of the segments of one chord are equal to the product of the segments of a second chord, the following relationship may be used by the processor arrangement 64 to determine an occupant's minimum seating and/or steering wheel position requirements, using the seat belt extraction information and predetermined information of the distance between two seat belt anchoring points (or other suitable reference points). Figure 10A shows the path of a lap belt and a shoulder belt with respect to a vehicle seat. The following example assumes a vehicle seat architecture that would provide an average chord length of 25" between seat belt anchoring points XY and YZ, as shown in Figure 10A. This chord length may vary based upon the particular seat architecture for a particular vehicle.
In an example vehicle seating arrangement, the design distances are as follows: XY = 31" and YZ = 19", so that 50" = total chord length and 25" = average chord length. Figure 10B shows an extended view of a path of a lap or shoulder belt for use in determining a protrusion amount or a depth of a person seated in the vehicle seat. In particular, as shown in Figure 10A, the extracted seat belt forms two arcs XY and YZ, which are at a height of "h" from the seat-back chord lines XY and YZ. It is believed that the occupant's depression into
a softer seat does not substantially effect this computation, since it is only concerned with the actual protrusion of the occupant's chest relative to the position of the driver air-bag or passenger air-bag.
When chords intersect within a circle, the product of the segments of the first chord is equal to the product of the segments of the second chord. Therefore, in Figure 10B, c/2 * c/2
= h * x, and c2/4 = h * x. If, as stated above, the average chord length c is 25", then the solution for a 7" chest protrusion is as follows: 625/4 = 7x, so that 156.25 - 7x, and x = 22.32 (value x). Also, the diameter d = x + 7 = 29.32 (value h+x), and the radius r = V2 diameter ~ 14.66 (value R), so that the circumference = 29.32 * 3.1416 = 92.11 (value Circ). Since the angle A 2 = y2 c/r = 12.5/14.66 = .8526603 = 58.50 degrees, angle A = 58.50 * 2 - 117 degrees (value A). Where the length of the arc is directly proportional to the subtended angle, the arc length (or seat belt length) may be determined as follows: 360/92.11 = 117/L, so that L = 29.94 (value L). As two arcs are involved, each of length 29.94", the length of seat belt used in excess of the two average 25" chords of the example is as follows: 2(L - c) = 2(29.94 - 25) = 9.88" (value Extract). This represents the additional belt extracted as compared to a belted empty seat, which is available distance information for any particular vehicle.
An exemplary Table A (where the depths or protrusions h may be, for example, about 7" to 12" (where the average chord is 25" for a particular vehicle seat arrangement), is as follows:
TABLE A
"h" "x" "h+x" "R" "Circ" "AJ2" "A" "L" "Extract"
7" 22.32 29.32 14.66 92.11 58.50 117 29.94 9.88"
8" 19.53 27.53 13.77 86.49 65.2 130.4 31.33 12.66"
9" 17.36 26.36 13.18 82.81 71.5 143 32.89 15.78"
10" 15.63 25.63 12.82 80.52 77.17 154.34 34.52 19.04"
11" 14.20 25.20 12.60 79.17 82.78 165.55 36.41 22.82"
12" 13.02 25.02 12.51 78.60 87.71 175.42 38.30 26.60"
The computations may be expressed for any average chord c of the arcs XY and YZ, where c = average seat chord length, h = occupant (chest) protrusion from a predetermined
seat-back line, and L = average arc length, as follows: c2/4/h + h = d, where d/2 = r, so that 3.1416 * d = circumference, and %c/r = sin 5 angle a, so that 360/3.1416 *d = angle a (degrees) L, so that L may be used to determine the extracted seat belt length ESBL, where ESBL = 2(L- c) = extracted belt length in excess of chords XY and YZ (that is, the seat belt length required for an unoccupied seat).
Thus, an occupant's protrusion from a predetermined seat-back line may be determined based on the extracted seat belt length ESBL. Accordingly, the processor arrangement 64 may be used to determine an effective maximum forward seat position slide (and/or vehicle steering wheel position of a telescoping and/or tilting steering wheel) to maintain a 10" safe distance clearance may be determined as described herein. For example, if the extracted seat belt length ESBL is determined to be 13.50" (indicating a 9" protrusion in Table A), the effective position of the vehicle seat (and/or the steering wheel for a driver) should be set to maintain a minimum distance of about 19" from a predetermined reference line of the seat-back to the air-bag (that is, 19" is the 9" protrusion and the minimum air-bag to occupant distance of 10"). A manufacturer may establish such tables in any increment, adjusted for predetermined vehicle safety belt anchor distances (or other suitable reference points) at varying seat slide positions and unoccupied seat belt length.
As shown in Figure 10B, there is a mathematical relationship between seat belt extraction and the determination of an occupant's position relative to a known location of the steering wheel and the seat back location based upon each vehicle's design. Because of this and because of the relatively small variance in human chest depth, a ratio geared mechanical cable connection from the seat belt extractor and a forward seat slide limit maybe incorporated in different vehicles, even those having manual seat slides.
Upon fastening the seat belt, the seat slide limit would preclude further seat forward motion in which case the driver would manually retract the pedal slide using lever 12, as shown in Figure 1 A, to a comfortable driving position. Should the seat be closer than the seat limit allowed, a simple visual indicator may be used to inform the driver that the seat must be retracted to maintain a safe clearance. Since this would not require computer controls, electric seats or distance sensors, it may be incorporated in all vehicles, at the relatively minor cost of a cable connection from a belt extractor to a seat slide limit, and the manually adjustable pedal slide as shown in Figure 2A.
The entire disclosure of the priority applications is hereby incorporated by reference, as necessary.
The examples of distances such as the minimum clearance from an air-bag are discussed throughout this specification, but these distances may vary on a case-by-case basis. In addition, the above-described embodiments are only exemplary and there are variations and modifications of the disclosed exemplary embodiments and/or exemplary method. These variations and modifications are considered to be within the scope of the claimed inventions.