WO1999044865A1 - Lap mounted inflatable bag and method of use - Google Patents

Lap mounted inflatable bag and method of use Download PDF

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Publication number
WO1999044865A1
WO1999044865A1 PCT/US1999/004561 US9904561W WO9944865A1 WO 1999044865 A1 WO1999044865 A1 WO 1999044865A1 US 9904561 W US9904561 W US 9904561W WO 9944865 A1 WO9944865 A1 WO 9944865A1
Authority
WO
WIPO (PCT)
Prior art keywords
vehicle
bag
occupant
belt
restraint system
Prior art date
Application number
PCT/US1999/004561
Other languages
French (fr)
Inventor
Donald J. Lewis
Original Assignee
Universal Propulsion Company, Inc.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Universal Propulsion Company, Inc. filed Critical Universal Propulsion Company, Inc.
Priority to KR1020007009761A priority Critical patent/KR20010041573A/en
Priority to AU29774/99A priority patent/AU2977499A/en
Priority to BR9908471-6A priority patent/BR9908471A/en
Priority to EP99911037A priority patent/EP1060095A1/en
Priority to JP2000534436A priority patent/JP2002505226A/en
Publication of WO1999044865A1 publication Critical patent/WO1999044865A1/en

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60RVEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
    • B60R21/00Arrangements or fittings on vehicles for protecting or preventing injuries to occupants or pedestrians in case of accidents or other traffic risks
    • B60R21/01Electrical circuits for triggering passive safety arrangements, e.g. airbags, safety belt tighteners, in case of vehicle accidents or impending vehicle accidents
    • B60R21/017Electrical circuits for triggering passive safety arrangements, e.g. airbags, safety belt tighteners, in case of vehicle accidents or impending vehicle accidents including arrangements for providing electric power to safety arrangements or their actuating means, e.g. to pyrotechnic fuses or electro-mechanic valves
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60RVEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
    • B60R21/00Arrangements or fittings on vehicles for protecting or preventing injuries to occupants or pedestrians in case of accidents or other traffic risks
    • B60R21/02Occupant safety arrangements or fittings, e.g. crash pads
    • B60R21/16Inflatable occupant restraints or confinements designed to inflate upon impact or impending impact, e.g. air bags
    • B60R21/18Inflatable occupant restraints or confinements designed to inflate upon impact or impending impact, e.g. air bags the inflatable member formed as a belt or harness or combined with a belt or harness arrangement
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60RVEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
    • B60R22/00Safety belts or body harnesses in vehicles
    • B60R22/12Construction of belts or harnesses
    • B60R22/14Construction of belts or harnesses incorporating enlarged restraint areas, e.g. vests, nets, crash pads, optionally for children
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60RVEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
    • B60R21/00Arrangements or fittings on vehicles for protecting or preventing injuries to occupants or pedestrians in case of accidents or other traffic risks
    • B60R2021/0065Type of vehicles
    • B60R2021/0067Buses
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60RVEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
    • B60R21/00Arrangements or fittings on vehicles for protecting or preventing injuries to occupants or pedestrians in case of accidents or other traffic risks
    • B60R2021/0065Type of vehicles
    • B60R2021/0093Aircraft

Definitions

  • Inflatable elements, bag or belt, deploying from locations adjacent vehicle occupants have been proposed and suggested to distribute belt loading during a collision (U.S. Patent No. 3,682,498 and 3,841,654).
  • the present invention comprises an occupant vehicle restraint system in which a configured inflatable air bag is supported by a lap belt.
  • the lap belt is positioned adjacent the bag or in a passageway in the air bag which passageway is part of the inflatable pressure-retaining envelope of the bag.
  • the bag is sized and shaped so that the force of the occupant ' s torso tending to move forward in a rapid deceleration of the vehicle is restrained by the bag engaging a sufficiently large support area consisting of the top portion of the occupant ' s legs and variably seat surface between the occupant's legs.
  • the belt-receiving passageway m ay be located so that a rear portion of the bag is inflatable between the belt and the occupant and the remainder of the bag is inflatable forward of the belt to prevent any substantial rotation of the torso.
  • a rear portion of the bag when inflated tightens the lap belt as such rear portion presses against the occupant's lap upper thigh portion and lower stomach area.
  • the forward portion of the bag inflates to serve as structural air stiffened column to provide a restraint against the occupant ' s forward movement and rotation of the occupant's torso.
  • the present inventive restraint system and its method of operation utilizes an air bag deployed from the lap belt area which bag as deployed is fully supported and constrained by (1) the lap belt and (2) surfaces including occupant's legs and the surface upon which the occupant is seated.
  • the invention is particularly useful for occupant seated in seats that are not adjacent a dashboard or a wheel post. Occupants in the back seats in passenger land vehicles and airplane passengers are readily protectable utilizing the present inventive restraint system.
  • Fig. 1 is a perspective view of an occupant in a front seat with a lap belt and folded air bag prior to inflation;
  • Fig. 2 is a partial perspective view similar to Fig. 1 showing the folded bag in a rupturable pouch prior to inflation and illustrating the looseness with which the belt may be worn and still be effective;
  • Fig. 3 is a diagrammatic plan view of the occupant and inflated bag
  • Fig. 4 is a view similar to Fig. 1 showing the bag as first inflated
  • Fig. 5 is a view similar to Fig. 4 after inflation with the occupant's torso having moved forward a small distance;
  • Fig. 6 is an alternative embodiment in which the bag includes an upper blister for additional head support to further reduce head rotation to a lesser angle;
  • Fig. 7 is a bottom view of the bag prior to folding
  • Fig. 8 is a partially folded view of the bag
  • Fig. 9 is a schematic diagram showing the forces and torques created during rapid deceleration of the vehicle and bag deployment;
  • Fig. 10 is a further schematic diagram showing forces and torques upon initial bag inflation where the lap belt is positioned within a bag passageway;
  • Fig. 11 is a front elevational view of an embodiment of the present invention in which an inflatable member is mounted in a lap belt system which includes an inflation arrangement ;
  • Fig. 12 is a front elevational view of an inflated bag of particle shape
  • Fig. 13 is a front elevational view of an inflated bag with upper expansion pockets prior to their inflation;
  • Fig. 14 is a side perspective view of the bag of Fig. 12 after inflation;
  • Fig. 15a is a side perspective view of the bag of Fig. 13 with an upper expansion pocket being deployed;
  • Fig. 15b is a view similar to Fig. 15a in which a further pocket is deployed;
  • Fig. 15c is a side elevational view in which the bag pockets shown in Figs. 15a and 15b are fully deployed;
  • Fig. 16a is a front elevational view of a bag having side pockets which bag has been inflated without side pocket deployment ;
  • FIG. 16b is a view similar to Fig. 16a in which the side pockets are deployed;
  • Fig. 16c is a front elevational view of a bag including a head side support section
  • Fig. 17 is a partial schematic view of the belt sections, tongue and buckle arrangement with an undeployed inflatable member
  • Fig. 18 is a partial sectional view through the tongue unit and inflatable member of Fig. 17;
  • Fig. 19 is a schematic view of a belt arrangement with the inflator in the buckle and the connectable tongue unit;
  • Fig. 20 is a schematic view of a belt arrangement showing the inflatable member attached to the buckle and with the inflator in the tongue unit;
  • Fig. 21 is a perspective view showing the tongue unit and buckle detached with transformer portions on each;
  • Fig. 22 is a sectional exploded view of a belt anchor
  • Fig. 22a is a side view of the anchor of Fig. 22 including the belt section;
  • Fig. 22b is a sectional view of a belt section taken along line 22b-22b of Fig. 22;
  • Fig. 22c is a view similar to Fig. 22b with the belt section having a gas passage formed therein by gas pressure;
  • FIG. 23 is a front elevational view of a further bag embodiment with an opening therethrough for centered lap belt buckle and tongue manipulation;
  • Fig. 24 is a side perspective view of a further configured bag embodiment with the lap belt positioned against the bag surface;
  • Fig. 24a is a schematic diagram of the bag of Fig. 24 positioned illustrating a passenger's torso and legs at a 90° 0 angle;
  • Fig. 24b is a further schematic similar to Fig. 24a in which the torso-to-leg angle is greater than 90°;
  • Fig. 24c is a further schematic in which the angle is 90° and bag sections theoretically overlap;
  • Fig. 25 is a perspective view of occupants in rows of seats in which lap mounted bags deploy row-by-row; 0
  • Fig. 26 is a schematic of row of seats, inflation arrangements and controls for such inflation arrangements.
  • Fig. 27 is a schematic and circuit diagram for 5 controlling inflation of a bag or bags properly timed after rapid vehicle deceleration.
  • occupant's (0) seat 12 with seat “ surface 12s and seat back 12b are mounted on vehicle floor 13.
  • Occupant (0) is shown in passenger seat 12 with lap belt 16 across occupant's (0) lap.
  • Lap belt right portion 16a is engaged in belt extension 24 which in turn is anchored in right floor anchor 14 in vehicle floor 13 and the left belt portion 16b is secured to the vehicle floor 13 by right floor anchor 15.
  • lap belt may have two sections and c a buckle.
  • bag 18 with exterior inflatable cloth body 19 has a cloth passageway 21 between slot portals 21a, 21b through which lap belt 16 is passed.
  • Cloth body 19 together with cloth passageway 21 0 comprise the pressure-retaining envelope 18e of bag 18 into which envelope 18e the gases of inflation are introduced or formed.
  • Lap belt 16 is readily slidable back and forth through passageway 21 when bag 18 is deflated. Such movement provides for adjustment of bag 18 with respect to the 5 occupant.
  • Bag 18 ' s gas inlet neck 22 (Fig. 7) can be connected to gas conduit 23 extending from a remote location such as the floor 13.
  • Gas conduit 23 is supplied gas from a storage gas container or a pyrotechnic gas inflator or a combination thereof, and alternately the inflation source may o be contained within the bag 18.
  • FIG. 2 an alternative embodiment is shown in which folded bag 18 is covered by an elongated rupturable pouch 20. Bag 18 is shown folded for positioning in pouch 20 in a ready-to-deploy position with belt 16 loosely positioned 5 for the comfort of the occupant.
  • This alternative system has a gas-generating inflator positioned in bag 18 or pouch 20.
  • Fig. 4 shows bag 18 with the alternate inflation entrance of gases from conduit 23 through neck 22.
  • Bag 18, 0 as inflated, is generally round in shape as viewed from above (Fig. 3) and generally triangular in shape as viewed from the side (Fig. 4) .
  • Bag 18 has a bottom seat surface and leg engaging surface 18a; a torso engaging surface 18b and front non-engaging surface 18c. Surfaces 18a and 18b intersect along occupant's waistline (WL) . Since belt 16 passes through bag passageway 21 which is distance (d) from the occupant's waistline (WL) , the inflation of bag portion 18r to the rear of belt 16 pushes occupant (0) back and down in his or her seat as bag 18 is first inflated (see Figs. 4 and
  • inflation of bag 18 is accomplished sufficiently rapidly, using inflators of stored gas or pyrotechnic type or combinations thereof, so that the occupant's lap belt 16 is tightened by inflation of the rear bag portion 18r prior to forces of deceleration acting on the occupant's (0) torso (T) which force tends to move the torso
  • torso (T) forward in rotational movement about belt 16. Only a few degrees of torso (T) rotation is permitted by the compression of bag 18. Any additional torso rotation will depend on the occupant's seated position and whether bag 18 rests on the occupant's legs, seat 12s or combination of both. Bag 18 is shown in Fig. 5 engaging seat 12s over area 12a as torso (T) is decelerated. Torso rotation is preferably less than 10° from the vertical. However, depending on the occupant's size and the size and shape of the bag, rotation of the torso may be up to 30°.
  • - horizontal force (F) represents the force exerted by occupant's torso at a distance X from lap belt 16 creating a torque (T 1 ) .
  • torque (T x ) bag 18 To resist torque (T x ) bag 18 generates an equal and opposite torque (T 2 ) .
  • Torque (T 2 ) is force (F 2 ) times distance (Y) .
  • Fig. 10 is also a schematic showing the embodiment in which the belt passes through the bag with bag portion 18r inflating between the belt and the occupant.
  • Initial bag inflation causes the bag to push the occupant back of vertical line (V) 15° (note the 90° angle of Fig. 9 and the 15 105° angle of Fig. 10) .
  • Bag portion 18i pushes the occupant down in the seat and bag portion 18h pushes occupant back in his seat.
  • Bag 18 when inflated is restrained from forward movement
  • Bag 18 rotates a few degrees as it is acted on the forces of the occupant's torso deceleration. Bag 18 is shaped and sized to prevent substantial torso rotation of any occupant including a large man. Smaller occupants will experience even less torso rotation. Bag 18 has a bag exterior surface 18a which engages a substantial area of 25 occupant's legs and seat surface between the occupant's waist and knees. Bag 18 also has a surface 18b for engaging a substantial portion of torso from the waist to the head. Bag
  • bag surface 18a engages 1/3 to 2/3 of occupant's upper legs.
  • Upper legs are the portion of the legs between the hips and knees. Bag surface 18a also engages the seat surface over the seat surface area between occupant's legs.
  • bag 18 includes deployable blister 34. As occupant's (0) torso (T) exerts forces of compression on bag 18 increasing the gas pressure therein to a selected threshold allowing stitches 35 to rupture blister section 34 inflate to provide support for the occupant ' s (0) and head (H) .
  • unmflated bag 18 has bottom surface 31, passage outlet ends 21a, 21b and gas inlet 22.
  • Fig. 7 shows unmflated bag 18 with outside portions 28, 29 folded to positions adjacent central bag bottom portion 30 which central portion 30 is approximately the width of belt 16.
  • Fig. 11 illustrates a further embodiment of the present invention m which the inflatable member 36 which may be of any shape and configuration is foldably mounted on lap belt system 38 which system has positioned m it the entire inflation arrangement.
  • Tongue unit 39 is connected to a tongue belt section 41 which m turn is attached to tongue belt section anchor 43.
  • the belt system 38 also includes a buckle 45, a buckle belt section 46 and a buckle anchor 48. Occupant (0) seated on seat 49 is restrained by belt system 38. Upon inflation of inflatable member 36 further occupant protection is provided as described below.
  • FIG. 12 an inflatable member m the form of bag 55 is shown which bag 55 has a particular shape including leg-engaging bag wings 56, 57 and a central blister section
  • bag 55' consists of bag body 60 made of two stitched together bag panels 60a and 60b (not shown) which include two upper stitched bag body pockets 64, 65 formed by tucking bag body panel material into the interior of bag 55' and stitching such tucked-in panels to adjacent bag panels employing stitched generally-horizontal rows 67,
  • Bag body pockets 64, 65 are deployable under selected circumstances described below to increase the bag size and shape.
  • Fig. 14 deployment of bag 55 including its blister section 59 is shown (see also Fig. 12) .
  • the forward movement of occupant (0) is shown in dashed lines.
  • Figs. 15a-c there is shown the stages of deployment of body pockets 64, 65 during inflation of bag 55' when occupant -induced internal bag pressures reach predetermined levels.
  • the reason for pocket deployment is to increase the size and height of bag 55 ' to serve larger, taller and heavier occupants.
  • forces are exerted on the bag as it controls the occupant ' s movement including forward torso movement causing bag pressure to increase. If the occupant (0) is sufficiently larger and heavy, pressure will build up in bag
  • FIG. 15c shows bag 55' with both pockets 64, 65 fully deployed. As bag size increases by pocket deployment bag pressure is reduced for a given amount of gas in the bag; however, the forces acting on the occupant may remain the
  • Fig. 16a shows use of side pockets 61, 62 created by c generally-vertical stitch rows 61a, 62a. Deployment of side pockets 61, 62 due to stitching failure are shown in Fig. 16b.
  • Fig. 16c illustrates bag 55" with a head protecting portion 63. Stitching bag panels using any suitable patterns are contemplated by the present invention to provide additional inflatable member size during inflation and the 0 creation of forces resulting from occupant restraint.
  • deployment of larger inflatable member volumes to accommodate 5 larger occupants may be accomplished by fabricating inflatable members, such as bags, of expansible or stretchable material.
  • inflatable members such as bags, of expansible or stretchable material.
  • Members made of fabrics or other materials which expand or stretch when inflated and when additional forces are applied by the occupant (0) during or 0 after inflation are alternatively useful alone or in combination with non-stretchable materials.
  • Inflating systems positioned within the belt arrangement include a crash detector which sends a signal to an initiator which in turn initiates the function of an inflator causing 5 the rapid flow of gases to the inflatable member.
  • a crash detector which sends a signal to an initiator which in turn initiates the function of an inflator causing 5 the rapid flow of gases to the inflatable member.
  • tongue unit 39 includes tongue 0 housing 70, tongue prong 71, inflator 72, roller clamp 73 for adjusting the effective length of belt section 41. Also shown are inflatable flexible member panels 36a, 36b of
  • Header 77 includes header lock section 78. After panels 36a, 36b are positioned on and around pins 76a, 76b slide lock section 78 is forced in place c to hold the inflatable member panels 36a, 36b in place. Also shown is rupturable diaphragm 81 in gas passageway 82.
  • inflator 72 is located in buckle 45 and the origin of the electrical signal to cause inflator
  • Electrical wire 85 with tandemnly-connected wire sections 85a, 85b pass from crash detector (not shown) through belt section 41 and tongue unit 39 to buckle 45 into inflator 72.
  • Wire section 85b includes a socket 79 and wire section 85a includes a tapered head 80 shaped to enter socket 5 79 for electrical connection.
  • This arrangement permits the crash detector to be located in the anchor that serves belt section 41 to provide the necessary tongue-to-buckle detachable connection.
  • the inflator 72 is located in the tongue unit 39 and the inflatable member 36 is 0 mounted on the buckle 45. Gases generated in inflator 72 travel in gas passageway segments 86, 87 which segments are detachably connected by a nipple 88 and socket 91.
  • Inflator 72 may be any suitable inflator; however, it is preferably a hybrid inflator with a pressurized housing 5 having walls and with the propellant positioned therein spaced from the walls. Any suitable pyrotechnic material or propellant may be used to create the required gases. Preferable propellants whose burn time is in the sub- millisecond range when combusted at a pressure of 0 approximately 25,000 psi are used in the practice of this invention. The materials (propellants) utilized should have extremely short function times. The materials should have
  • the 7019a propellant is a propellant material including an oxidizer such as ammonium nitrate; a nitramine (preferably thermally stable) and a binder.
  • the nitramine may be cyclo-1 , 3 , 5-trimethylene-2 , 4 , 6-trinitramine (RDX) or cyclo-1, 3 , 5 , 7-tetramethylene-2 , 4, 6, 8-tetranitramine (HMX) .
  • Propellant 7019a is a solvent processed propellant which leaves a microscopic fine porosity throughout the quantity of propellant material positioned in inflator 72.
  • the binder should be a small percentage i.e. 4% of the material.
  • Propellant components should be proportioned to accomplish rapid and complete burning to produce gases which are environmentally sound and burn to reduce or eliminate inflator wall heating.
  • the microscopic fine porosity in the propellant allows it to be produced with granules instead of as a single grain piece with each granule having a small web.
  • the granules have the advantage of not being susceptible to cracks and the micro-porosity as well as the surface area created by the micro granules enable the propellant to be extremely quickly ignited.
  • the propellant has high thermal stability and therefore requires high temperature to ignite it.
  • the small granules and microporse propellant leading to the ultra-thin web facilitate the fact that the propellant will be consumed before it can be explosively hurled into contact with the c walls including side walls of the inflator 72.
  • the reduction or elimination of propellant striking the walls of the inflator housing reduces the rise in temperature of the inflator and facilitates its use adjacent or even in contact with the occupant .
  • inflator propellant materials may in addition include Hercules "Hi-Temp” brand propellant.
  • electrical signals are passed from tongue unit 39 to buckle 45 employing a transformer 93 with one 5 transformer portion 94 of the transformer 93 in the buckle 45 and forming a part of buckle surface 45s and the other portion 95 of the transformer 93 in the tongue unit 39 and forming a part of tongue unit surface 39s.
  • Electrical signals generated in transformer portion 94 cause electrical 0 signals to be generated in transformer portion 93.
  • Such signal transfer permits an electrical signal generated on one side of the belt system to be transmitted to the other side of the belt system so that the crash detector can be located on either side of belt system 38.
  • crash detector 90 Also shown in Fig. 21 is crash detector 90 positioned on the tongue side for producing 5 an electrical signal upon vehicle deceleration.
  • anchor 43 includes anchor cover 92 and anchor shielded housing 97 for shielding against extraneous radio waves or other waves that might prematurely activate the initiator. Also shown is anchor swivel unit 98. Initiator 101 is mounted in housing 97 and an inflator (not shown) is positioned in swivel unit 98. Gases generated in swivel unit 98 by the inflator pass through exit neck 103, connector 105 into belt 104 which belt is constructed of two layers 104a, 104b. Layers 104a, 104b separate upon application of gas-generated pressure to form gas passage 106
  • the crash detector in anchor 43 may be battery powered with low voltage being indicated by a light or an audible signal. Since the electrical requirements to operate the system are small, batteries located in the anchors may be used with replacement required only after five or more years .
  • FIG. 23 an alternate bag design is shown in which bag 108 has a central opening 107 to permit buckle 45 and tongue unit 39 to be readily operated in the central area of the occupant's lap.
  • Central opening 107 is not part of the bag pressure-retaining envelope.
  • bag passageway 102 is not part of the pressure-retaining envelope of bag 108.
  • Central opening 107 may through alternate bag design be located on either side of the center of bag 108 as shown in Fig. 23.
  • Belt 109 passes through bag passageway 102 which is divided into passageway sections 102a, 102b which sections 102a, 102b are separated by bag central opening 107.
  • FIGs. 24, 24a-c a further bag embodiment is shown in Figs. 24, 24a-c, which bag 110 consists of upper and lower sections 111, 112 and waist section 113 with lap belt 116 passing
  • Belt 110 is positioned against bag waist section 113 upon inflation.
  • Upper bag section 111 engages occupant's torso and lower bag c section 112 engages the occupants legs and seat surface.
  • Inflated belt section 113 which has belt 116 engaging its outer surface positions belt 116 distance X from occupant's
  • Bag sections 111, 112 engage at line L and with added forces during deceleration and inflation bag portions 111, 112 may be forced against one another.
  • bag sections 111, 112 are sized to form a ninety degree (90°) angle A between the torso and legs of occupant (O) .
  • Fig. 24b shows bag 110' sized to form an angle of 105° or more when sections 111',
  • bag sections 111", 112" are of bag 110" are shown being distorted by forces applied by occupant (0) as sections 111", 112" compress.
  • Volume V represents the volume of theoretical overlap of sections 111", 112" if no bag section compression occurred.
  • volume or pressure of gases supplied to bag section 111" may differ from the volume or pressure of gases fed to the bag section 112" .
  • each row or portion should be equipped with a separate crash detector.
  • the present invention is particularly adaptable for use 30 in aircraft or other vehicles where lap belts have been in common use for many years. Bags can be deployed from the lap belt area without need for installation of equipment in the
  • the invention provides protection for occupants, including pilots and passengers, of large or small aircraft.
  • Gas supply unit 128 includes an initiator, an inflator and gas supply lines (not shown) which lines supply the bags mounted on the lap belts positioned across laps of the occupants in their seats.
  • the inflator is sized to supply the air bags which serve each of the two (2) seats in row 124.
  • Gas supply unit 128 also includes a crash detector or other arrangement for creating a crash signal when a selected deceleration occurs at row 124. The crash triggers the firing system creating a crash signal which in turn causes the initiator to ignite the inflator to rapidly create gases and supply them to the air bags in row 124.
  • the air bags of forward row 124 are in a state of deployment in which the bags have been fully filled with gas and the passengers' torsos have swung forward.
  • Fig. 25 Also shown in Fig. 25 is middle row 130 in which bag deployment has started and rearward row 132 in which the crash detector has not yet caused the air supply system to commerce operation.
  • a gas supply unit may be positioned adjacent each individual seat in each row.
  • Each supply unit may have its own crash detector firing system and inflator.
  • An alternative arrangement for sequentially initiating bag deployment in a large aircraft is to have a single crash detector serve more than one row of seats.
  • the signal serving the more rearward rows is preferably delayed so that bag deployment occurs when it can provide maximum protection for each of the occupants in each row. Deployment is timed to occur sufficiently in advance of rapid deceleration of the occupants to allow for bag inflation to provide maximum protection from injury or death.
  • crash detector 133 serves three rows of seats. Forward row 135 has four (4) seats 135a-d. Each seat has its own gas supply unit 136a-d. Middle row 138 with four (4) seats 138a-d has each of its seats served by a gas supply unit 139a-d and rearward row 141 with seats 141a-d have gas supply units 142a-d. Crash detector 133 supplies signals to each row along electrical conduits 144, 145 and 146. The signals transmitted along conduit 144 cause the start of initiator, followed by, inflator activation, immediately after detector 133 measures a sudden
  • the signal transmitted along conduit 145 (which is simultaneously transmitted with the conduit signal) is delayed by time delay 148 so that bag deployment in middle row 138 occurs after row 135 deployment.
  • the signal c transmitted along conduit 146 again simultaneously transmitted with the 144 conduit signal, is also delayed by time delay 149 so that rearward row 141 is deployed after middle row 138.
  • An aircraft with forty (40) rows of seats would be equipped with a dozen or more crash detectors .
  • the crash detector and firing signal unit 133 includes a firing system 149 produces a low voltage (amperage) signal.
  • the system is preferably battery powered.
  • circuitry for a crash detector is 5 shown in which actuating lever 150 is moved with aircraft deceleration Lever 150 moves when deceleration in that section of the plane occurs to in turn move switch arms 151a,
  • switch arms 151a, 152a engage the 0 upper stationary contact 151u, 152u of switches 151, 152 which short circuits capacitor 155 and resistor 156.
  • the timing circuit 160 is powered by battery 161. 5
  • actuating lever 150 moves switch arms 151a, 152a to their lower positions causing a voltage to be applied by battery 161 through diode 162 to start terminal
  • Timing circuit 160 times the preselected period. At the end of the period, the timing circuit 160 produces a series
  • the flow of current through the transistor 170 causes a relatively high voltage to be produced across the resistor 156.
  • This high voltage establishes a state of conductivity 5 in the transistor 156.
  • the transistor 156 becomes conductive, it has a relatively low impedance.
  • This causes a circuit to be established through the capacitor 172, the switch 152 (in the second state of operation) , the pyrotechnic squib 158 and the transistor 176.
  • the capacitor 0 172 then discharges through the pyrotechnic initiator 158 to fire the pyrotechnic initiator.
  • the firing of the pyrotechnic initiator 158 initiates the operation of the inflator to inflate bags in a passenger row.
  • Patent No. 5,335,598 is incorporated herein by reference.
  • the firing circuit 150 and initiator 158 may be housed in a single housing as disclosed and claimed in U.S. Patent 0 NO. 5,499,579 issued March 19, 1996 and owned by the assignee of the present invention.
  • U.S. Patent No. 5,499,579 is incorporated herein by reference.
  • the timing circuit 160 may utilize an input mechanism as the source of energy instead of a battery.
  • An input electrical pulse for example, of five (5) amperes and five (5) milliseconds, from an input mechanism is preferred rectified converting it to direct current which energy is stored in a capacitor as disclosed and claimed in U.S. Patent No. 5,507,230 issued April 16, 1996 and owned by the assignee of the present invention.
  • U.S. Patent No. 5,507,230 is incorporated herein by reference.
  • Faraday shielding may be placed around the firing circuit or internal filtering may be used or both.
  • the triggering signal may be filtered by a low pass filter (e.g. inductance and capacitance) to prevent noise from passing. Finite filtering may also be employed.
  • a device e . g. zener diode
  • the filtered triggering signal charges the capacitance in the low pass filter.
  • the capacitor charge causes a second transistor to become conductive, thereby producing a voltage across an impedance. This voltage triggers the first transistor to the conductive state to provide for the firing of the initiator.
  • the crash detector may be triggered by propagated energy waves such as radar waves rather than by aircraft deceleration.
  • a radar signal may be sent out by the airplane which signal would reflect off an object which is on a collision course with the airplane. The reflected signal would then
  • the crash detector 22 trigger the crash detector to start the sequence of inflation row by row of the occupants air bags prior to the collision.
  • a computer may be used to compute the time of the deceleration in various vehicle portions.
  • the time for deployment may be extended from twenty or forty milliseconds to 1000 milliseconds. For example, if an airplane traveling at 120 mph (176 ft. per second) and the bag is deployed when airplane is 176 ft from collision, a period of 1000 milliseconds may be provided for deployment to occur. Longer ° deployment times reduce the peak forces and pressure applied to passengers thus reducing the risk of injury by the bags during inflation.
  • the forces generated in the lap belts of the present 5 invention are about one thousand (1000) pounds per side.
  • Gas bag pressure upon full inflation is about 20 psig.
  • Inflation times are between 10 and 1000 milliseconds.
  • Inflatable members other than bags such as belts may be 0 useful in practicing the present invention.
  • the embodiments of Figs. 25-27 are also useful in vehicles other than airplanes such as trains, buses and elongated automobiles.
  • inventions may employ the same inflators using the same pyrotechnic materials and propellants described herein. 5

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Textile Engineering (AREA)
  • Air Bags (AREA)

Abstract

A vehicle restraint system for a seated occupant including an inflatable member (18) mounted on a lap belt (16) and restrained by the belt when inflated. The inflatable member (18) is sized and shaped so that one surface (18a) functions to limit rotation of the inflatable member (18) by engaging a substantial area including the occupant's lap and the seat thereunder. A rearward surface (18b) of the inflatable member (18) restrains occupant's torso movement. The belt (16) may pass through or around the inflatable member (18).

Description

LAP MOUNTED INFLATABLE BAG AND METHOD OF USE
Background of the Invention
Inflatable elements, bag or belt, deploying from locations adjacent vehicle occupants have been proposed and suggested to distribute belt loading during a collision (U.S. Patent No. 3,682,498 and 3,841,654).
Prior restraint systems have combined seat belts, including lap and shoulder components, with inflatable members. For example, vehicle air bags have been proposed to be mounted adjacent shoulder belts and lap belts for deployment upon rapid deceleration of a vehicle (U.S. Patent
No. 5,062,662). Other prior inflatable bag vehicle restraint systems have required that the bag be supported by a portion of the vehicle m front of the occupant (i.e., the dashboard or wheel post unit) . Further, prior lap belt mounted bags were deployable m front of the occupant ' s belt and have not caused the lap belt to have its slack removed by the inflation of the bag.
Finally, it has been proposed to provide bags for inflation between the occupant and shoulder straps (U.S. Patent No. 3, 971,569) .
None of the prior art proposals provide proper protection where the restraint system can only be deployable from and restrained by a lap belt area.
Related Application
This application is a contmuation-m-part of U.S. Patent Application No. 08/826,612 filed April 4, 1997 entitled "Lap Mounted Inflatable Bag And Method Of Use" which was m turn a continuation- m-part of U. S. Patent Application No. 08/665,121 filed June 14, 1996 entitled "Lap Mounted Inflatable Bag And Method Of Use" which application was abandoned October 8, 1997.
Summary of the Invention The present invention comprises an occupant vehicle restraint system in which a configured inflatable air bag is supported by a lap belt. The lap belt is positioned adjacent the bag or in a passageway in the air bag which passageway is part of the inflatable pressure-retaining envelope of the bag. The bag is sized and shaped so that the force of the occupant ' s torso tending to move forward in a rapid deceleration of the vehicle is restrained by the bag engaging a sufficiently large support area consisting of the top portion of the occupant ' s legs and variably seat surface between the occupant's legs. The belt-receiving passageway may be located so that a rear portion of the bag is inflatable between the belt and the occupant and the remainder of the bag is inflatable forward of the belt to prevent any substantial rotation of the torso.
By so locating the belt-engaging bag surface or the belt-receiving passageway, a rear portion of the bag when inflated tightens the lap belt as such rear portion presses against the occupant's lap upper thigh portion and lower stomach area. At the same time the forward portion of the bag inflates to serve as structural air stiffened column to provide a restraint against the occupant ' s forward movement and rotation of the occupant's torso.
The present inventive restraint system and its method of operation utilizes an air bag deployed from the lap belt area which bag as deployed is fully supported and constrained by (1) the lap belt and (2) surfaces including occupant's legs and the surface upon which the occupant is seated. The invention is particularly useful for occupant seated in seats that are not adjacent a dashboard or a wheel post. Occupants in the back seats in passenger land vehicles and airplane passengers are readily protectable utilizing the present inventive restraint system.
Brief Description of the Drawings
Fig. 1 is a perspective view of an occupant in a front seat with a lap belt and folded air bag prior to inflation;
Fig. 2 is a partial perspective view similar to Fig. 1 showing the folded bag in a rupturable pouch prior to inflation and illustrating the looseness with which the belt may be worn and still be effective;
Fig. 3 is a diagrammatic plan view of the occupant and inflated bag;
Fig. 4 is a view similar to Fig. 1 showing the bag as first inflated;
Fig. 5 is a view similar to Fig. 4 after inflation with the occupant's torso having moved forward a small distance;
Fig. 6 is an alternative embodiment in which the bag includes an upper blister for additional head support to further reduce head rotation to a lesser angle;
Fig. 7 is a bottom view of the bag prior to folding;
Fig. 8 is a partially folded view of the bag; Fig. 9 is a schematic diagram showing the forces and torques created during rapid deceleration of the vehicle and bag deployment;
Fig. 10 is a further schematic diagram showing forces and torques upon initial bag inflation where the lap belt is positioned within a bag passageway;
Fig. 11 is a front elevational view of an embodiment of the present invention in which an inflatable member is mounted in a lap belt system which includes an inflation arrangement ;
Fig. 12 is a front elevational view of an inflated bag of particle shape;
Fig. 13 is a front elevational view of an inflated bag with upper expansion pockets prior to their inflation;
Fig. 14 is a side perspective view of the bag of Fig. 12 after inflation;
Fig. 15a is a side perspective view of the bag of Fig. 13 with an upper expansion pocket being deployed;
Fig. 15b is a view similar to Fig. 15a in which a further pocket is deployed;
Fig. 15c is a side elevational view in which the bag pockets shown in Figs. 15a and 15b are fully deployed;
Fig. 16a is a front elevational view of a bag having side pockets which bag has been inflated without side pocket deployment ;
4 - Fig. 16b is a view similar to Fig. 16a in which the side pockets are deployed;
Fig. 16c is a front elevational view of a bag including a head side support section;
Fig. 17 is a partial schematic view of the belt sections, tongue and buckle arrangement with an undeployed inflatable member;
Fig. 18 is a partial sectional view through the tongue unit and inflatable member of Fig. 17;
Fig. 19 is a schematic view of a belt arrangement with the inflator in the buckle and the connectable tongue unit;
Fig. 20 is a schematic view of a belt arrangement showing the inflatable member attached to the buckle and with the inflator in the tongue unit;
Fig. 21 is a perspective view showing the tongue unit and buckle detached with transformer portions on each;
Fig. 22 is a sectional exploded view of a belt anchor;
Fig. 22a is a side view of the anchor of Fig. 22 including the belt section;
Fig. 22b is a sectional view of a belt section taken along line 22b-22b of Fig. 22;
Fig. 22c is a view similar to Fig. 22b with the belt section having a gas passage formed therein by gas pressure;
5 - Fig. 23 is a front elevational view of a further bag embodiment with an opening therethrough for centered lap belt buckle and tongue manipulation;
π Fig. 24 is a side perspective view of a further configured bag embodiment with the lap belt positioned against the bag surface;
Fig. 24a is a schematic diagram of the bag of Fig. 24 positioned illustrating a passenger's torso and legs at a 90° 0 angle;
Fig. 24b is a further schematic similar to Fig. 24a in which the torso-to-leg angle is greater than 90°;
5 Fig. 24c is a further schematic in which the angle is 90° and bag sections theoretically overlap;
Fig. 25 is a perspective view of occupants in rows of seats in which lap mounted bags deploy row-by-row; 0
Fig. 26 is a schematic of row of seats, inflation arrangements and controls for such inflation arrangements; and
Fig. 27 is a schematic and circuit diagram for 5 controlling inflation of a bag or bags properly timed after rapid vehicle deceleration.
Description of the Preferred Embodiments
In Figs. 1, 3 and 4, occupant's (0) seat 12 with seat " surface 12s and seat back 12b are mounted on vehicle floor 13. Occupant (0) is shown in passenger seat 12 with lap belt 16 across occupant's (0) lap. Lap belt right portion 16a is engaged in belt extension 24 which in turn is anchored in right floor anchor 14 in vehicle floor 13 and the left belt portion 16b is secured to the vehicle floor 13 by right floor anchor 15. Alternatively, lap belt may have two sections and c a buckle.
With reference in particular to Fig. 3, bag 18 with exterior inflatable cloth body 19 has a cloth passageway 21 between slot portals 21a, 21b through which lap belt 16 is passed. Cloth body 19 together with cloth passageway 21 0 comprise the pressure-retaining envelope 18e of bag 18 into which envelope 18e the gases of inflation are introduced or formed. Lap belt 16 is readily slidable back and forth through passageway 21 when bag 18 is deflated. Such movement provides for adjustment of bag 18 with respect to the 5 occupant. Bag 18 ' s gas inlet neck 22 (Fig. 7) can be connected to gas conduit 23 extending from a remote location such as the floor 13. Gas conduit 23 is supplied gas from a storage gas container or a pyrotechnic gas inflator or a combination thereof, and alternately the inflation source may o be contained within the bag 18.
Turning to Fig. 2, an alternative embodiment is shown in which folded bag 18 is covered by an elongated rupturable pouch 20. Bag 18 is shown folded for positioning in pouch 20 in a ready-to-deploy position with belt 16 loosely positioned 5 for the comfort of the occupant. This alternative system has a gas-generating inflator positioned in bag 18 or pouch 20.
Fig. 4 shows bag 18 with the alternate inflation entrance of gases from conduit 23 through neck 22. Bag 18, 0 as inflated, is generally round in shape as viewed from above (Fig. 3) and generally triangular in shape as viewed from the side (Fig. 4) . Bag 18 has a bottom seat surface and leg engaging surface 18a; a torso engaging surface 18b and front non-engaging surface 18c. Surfaces 18a and 18b intersect along occupant's waistline (WL) . Since belt 16 passes through bag passageway 21 which is distance (d) from the occupant's waistline (WL) , the inflation of bag portion 18r to the rear of belt 16 pushes occupant (0) back and down in his or her seat as bag 18 is first inflated (see Figs. 4 and
5) . This action also removes any slack that may have existed in belt 16 due to looseness of wearing. Further, the inflation of the bag 18 and the creation of inflated bag space 18 also displaces bag over spaces 18h and 18i toward the occupant's chest and upper leg, respectively. Front bag portion 18f, the remaining portion of bag 18, is forward of the belt 16. Front bag portion 18f functions to support and resist rotation of occupant's (0) torso (T) as forces of vehicle deceleration act on torso (T) . Bag 18 may also include a set up reinforcing cloth panel 25 to strengthen bag
18 is the belt -engaging area which must withstand forces of inflation and occupant restraint as the vehicle decelerates.
It is contemplated that inflation of bag 18 is accomplished sufficiently rapidly, using inflators of stored gas or pyrotechnic type or combinations thereof, so that the occupant's lap belt 16 is tightened by inflation of the rear bag portion 18r prior to forces of deceleration acting on the occupant's (0) torso (T) which force tends to move the torso
(T) forward in rotational movement about belt 16. Only a few degrees of torso (T) rotation is permitted by the compression of bag 18. Any additional torso rotation will depend on the occupant's seated position and whether bag 18 rests on the occupant's legs, seat 12s or combination of both. Bag 18 is shown in Fig. 5 engaging seat 12s over area 12a as torso (T) is decelerated. Torso rotation is preferably less than 10° from the vertical. However, depending on the occupant's size and the size and shape of the bag, rotation of the torso may be up to 30°.
With particular reference to schematic Fig. 9, ,- horizontal force (F) represents the force exerted by occupant's torso at a distance X from lap belt 16 creating a torque (T1) . To resist torque (Tx) bag 18 generates an equal and opposite torque (T2) . Torque (T2) is force (F2) times distance (Y) .
10
Fig. 10 is also a schematic showing the embodiment in which the belt passes through the bag with bag portion 18r inflating between the belt and the occupant. Initial bag inflation causes the bag to push the occupant back of vertical line (V) 15° (note the 90° angle of Fig. 9 and the 15 105° angle of Fig. 10) . Bag portion 18i pushes the occupant down in the seat and bag portion 18h pushes occupant back in his seat.
Bag 18 when inflated is restrained from forward movement
20 by lap belt 16. Bag 18 rotates a few degrees as it is acted on the forces of the occupant's torso deceleration. Bag 18 is shaped and sized to prevent substantial torso rotation of any occupant including a large man. Smaller occupants will experience even less torso rotation. Bag 18 has a bag exterior surface 18a which engages a substantial area of 25 occupant's legs and seat surface between the occupant's waist and knees. Bag 18 also has a surface 18b for engaging a substantial portion of torso from the waist to the head. Bag
18 may also be sized to support occupant's head. Preferably, bag surface 18a engages 1/3 to 2/3 of occupant's upper legs.
30 Upper legs are the portion of the legs between the hips and knees. Bag surface 18a also engages the seat surface over the seat surface area between occupant's legs. In a further alternative embodiment shown m Fig. 6, bag 18 includes deployable blister 34. As occupant's (0) torso (T) exerts forces of compression on bag 18 increasing the gas pressure therein to a selected threshold allowing stitches 35 to rupture blister section 34 inflate to provide support for the occupant ' s (0) and head (H) .
Turning to Fig. 6, unmflated bag 18 has bottom surface 31, passage outlet ends 21a, 21b and gas inlet 22. Fig. 7 shows unmflated bag 18 with outside portions 28, 29 folded to positions adjacent central bag bottom portion 30 which central portion 30 is approximately the width of belt 16.
Fig. 11 illustrates a further embodiment of the present invention m which the inflatable member 36 which may be of any shape and configuration is foldably mounted on lap belt system 38 which system has positioned m it the entire inflation arrangement. Tongue unit 39 is connected to a tongue belt section 41 which m turn is attached to tongue belt section anchor 43. The belt system 38 also includes a buckle 45, a buckle belt section 46 and a buckle anchor 48. Occupant (0) seated on seat 49 is restrained by belt system 38. Upon inflation of inflatable member 36 further occupant protection is provided as described below.
Turning to Fig. 12, an inflatable member m the form of bag 55 is shown which bag 55 has a particular shape including leg-engaging bag wings 56, 57 and a central blister section
59 which extends downwardly near to or against seat surface
51. Whether blister section 59 engages seat surface 51 depends on the extent to which occupant's legs are initially spread apart and the extent to which blister 59 of bag 55, as inflated, causes any further leg separation. Bag wings 56,
10 57 are positioned and shaped with widths d1 , d2, respectively so that they properly serve both large and small occupants.
Turning to Fig. 13, bag 55' consists of bag body 60 made of two stitched together bag panels 60a and 60b (not shown) which include two upper stitched bag body pockets 64, 65 formed by tucking bag body panel material into the interior of bag 55' and stitching such tucked-in panels to adjacent bag panels employing stitched generally-horizontal rows 67,
68 and 69. Bag body pockets 64, 65 are deployable under selected circumstances described below to increase the bag size and shape.
In Fig. 14 deployment of bag 55 including its blister section 59 is shown (see also Fig. 12) . The forward movement of occupant (0) is shown in dashed lines.
Turning to Figs. 15a-c, there is shown the stages of deployment of body pockets 64, 65 during inflation of bag 55' when occupant -induced internal bag pressures reach predetermined levels. The reason for pocket deployment is to increase the size and height of bag 55 ' to serve larger, taller and heavier occupants. As bag 55' inflates to reach its full size, forces are exerted on the bag as it controls the occupant ' s movement including forward torso movement causing bag pressure to increase. If the occupant (0) is sufficiently larger and heavy, pressure will build up in bag
55 to cause stitch rows 67, 68 and 69 to sequentially break and to deploy the body pockets 64, 65 as bag additions.
Stitching closer to the central portion of bag 55 ' will fail first. Fig. 15c shows bag 55' with both pockets 64, 65 fully deployed. As bag size increases by pocket deployment bag pressure is reduced for a given amount of gas in the bag; however, the forces acting on the occupant may remain the
11 same since the area over which the forces act has been increased.
Fig. 16a shows use of side pockets 61, 62 created by c generally-vertical stitch rows 61a, 62a. Deployment of side pockets 61, 62 due to stitching failure are shown in Fig. 16b. Fig. 16c illustrates bag 55" with a head protecting portion 63. Stitching bag panels using any suitable patterns are contemplated by the present invention to provide additional inflatable member size during inflation and the 0 creation of forces resulting from occupant restraint.
As an alternative to non-stretch inflatable member material and the fracturable stitching described above, deployment of larger inflatable member volumes to accommodate 5 larger occupants may be accomplished by fabricating inflatable members, such as bags, of expansible or stretchable material. Members made of fabrics or other materials which expand or stretch when inflated and when additional forces are applied by the occupant (0) during or 0 after inflation are alternatively useful alone or in combination with non-stretchable materials.
Inflating systems positioned within the belt arrangement include a crash detector which sends a signal to an initiator which in turn initiates the function of an inflator causing 5 the rapid flow of gases to the inflatable member. In Fig.
17 belt sections 41, 46, buckle 45, tongue unit 39 and uninflated member 36 are shown (see also Fig. 11) .
Turning to Fig. 18, tongue unit 39 includes tongue 0 housing 70, tongue prong 71, inflator 72, roller clamp 73 for adjusting the effective length of belt section 41. Also shown are inflatable flexible member panels 36a, 36b of
12 - inflatable member 36 which engage tongue header pins 76a, 76b, mounted in tongue header 77. Header 77 includes header lock section 78. After panels 36a, 36b are positioned on and around pins 76a, 76b slide lock section 78 is forced in place c to hold the inflatable member panels 36a, 36b in place. Also shown is rupturable diaphragm 81 in gas passageway 82.
In schematic Fig. 19, inflator 72 is located in buckle 45 and the origin of the electrical signal to cause inflator
72 to operate is located on the tongue side of the belt 0 arrangement. Electrical wire 85 with tandemnly-connected wire sections 85a, 85b pass from crash detector (not shown) through belt section 41 and tongue unit 39 to buckle 45 into inflator 72. Wire section 85b includes a socket 79 and wire section 85a includes a tapered head 80 shaped to enter socket 5 79 for electrical connection. This arrangement permits the crash detector to be located in the anchor that serves belt section 41 to provide the necessary tongue-to-buckle detachable connection. In Fig. 20, the inflator 72 is located in the tongue unit 39 and the inflatable member 36 is 0 mounted on the buckle 45. Gases generated in inflator 72 travel in gas passageway segments 86, 87 which segments are detachably connected by a nipple 88 and socket 91.
Inflator 72 may be any suitable inflator; however, it is preferably a hybrid inflator with a pressurized housing 5 having walls and with the propellant positioned therein spaced from the walls. Any suitable pyrotechnic material or propellant may be used to create the required gases. Preferable propellants whose burn time is in the sub- millisecond range when combusted at a pressure of 0 approximately 25,000 psi are used in the practice of this invention. The materials (propellants) utilized should have extremely short function times. The materials should have
13 web thicknesses (the thicknesses that the materials burn through during their combustion) that are small and that will complete combustion in a short time such as less than a millisecond. Universal Propulsion designated 7019a propellant may be used. The 7019a propellant is a propellant material including an oxidizer such as ammonium nitrate; a nitramine (preferably thermally stable) and a binder. The nitramine may be cyclo-1 , 3 , 5-trimethylene-2 , 4 , 6-trinitramine (RDX) or cyclo-1, 3 , 5 , 7-tetramethylene-2 , 4, 6, 8-tetranitramine (HMX) .
Propellant 7019a is a solvent processed propellant which leaves a microscopic fine porosity throughout the quantity of propellant material positioned in inflator 72. The binder should be a small percentage i.e. 4% of the material.
Propellant components should be proportioned to accomplish rapid and complete burning to produce gases which are environmentally sound and burn to reduce or eliminate inflator wall heating. The microscopic fine porosity in the propellant allows it to be produced with granules instead of as a single grain piece with each granule having a small web.
The granules have the advantage of not being susceptible to cracks and the micro-porosity as well as the surface area created by the micro granules enable the propellant to be extremely quickly ignited. The propellant has high thermal stability and therefore requires high temperature to ignite it.
In hybrid inflators where propellants are stored under pressure of a gas such as an inert gas, chemical degradation is not enhanced and further the high pressure aids markedly in providing a high speed ignition and burning capability to the system. Extremely short burning times are best accomplished by burning these propellants in a very high
14 pressure environment. Additionally, the small granules and microporse propellant leading to the ultra-thin web facilitate the fact that the propellant will be consumed before it can be explosively hurled into contact with the c walls including side walls of the inflator 72. The reduction or elimination of propellant striking the walls of the inflator housing reduces the rise in temperature of the inflator and facilitates its use adjacent or even in contact with the occupant .
0
Finally, inflator propellant materials may in addition include Hercules "Hi-Temp" brand propellant.
In Fig. 21, electrical signals are passed from tongue unit 39 to buckle 45 employing a transformer 93 with one 5 transformer portion 94 of the transformer 93 in the buckle 45 and forming a part of buckle surface 45s and the other portion 95 of the transformer 93 in the tongue unit 39 and forming a part of tongue unit surface 39s. Electrical signals generated in transformer portion 94 cause electrical 0 signals to be generated in transformer portion 93. Such signal transfer permits an electrical signal generated on one side of the belt system to be transmitted to the other side of the belt system so that the crash detector can be located on either side of belt system 38. Also shown in Fig. 21 is crash detector 90 positioned on the tongue side for producing 5 an electrical signal upon vehicle deceleration.
It is seen that when tongue and buckle are buckled and unbuckled, electricity and gas flow from one side of the lap belt to the other side of the lap belt which may be effected 0 y the detachable connections described above or any other suitable arrangement .
15 - In Fig. 22, 22a and 22b, anchor 43 includes anchor cover 92 and anchor shielded housing 97 for shielding against extraneous radio waves or other waves that might prematurely activate the initiator. Also shown is anchor swivel unit 98. Initiator 101 is mounted in housing 97 and an inflator (not shown) is positioned in swivel unit 98. Gases generated in swivel unit 98 by the inflator pass through exit neck 103, connector 105 into belt 104 which belt is constructed of two layers 104a, 104b. Layers 104a, 104b separate upon application of gas-generated pressure to form gas passage 106
(see Figs. 22a, 22b). Prior to inflation belt layers 104a,
104b may be stitched or glued together. The crash detector in anchor 43 (not shown) may be battery powered with low voltage being indicated by a light or an audible signal. Since the electrical requirements to operate the system are small, batteries located in the anchors may be used with replacement required only after five or more years .
Finally, referring to Fig. 23, an alternate bag design is shown in which bag 108 has a central opening 107 to permit buckle 45 and tongue unit 39 to be readily operated in the central area of the occupant's lap. Central opening 107 is not part of the bag pressure-retaining envelope. Similarly, as stated above bag passageway 102 is not part of the pressure-retaining envelope of bag 108. Central opening 107 may through alternate bag design be located on either side of the center of bag 108 as shown in Fig. 23. Belt 109 passes through bag passageway 102 which is divided into passageway sections 102a, 102b which sections 102a, 102b are separated by bag central opening 107.
Finally, a further bag embodiment is shown in Figs. 24, 24a-c, which bag 110 consists of upper and lower sections 111, 112 and waist section 113 with lap belt 116 passing
- 16 around bag 110 rather than through a bag passageway as described above in earlier embodiments. Belt 110 is positioned against bag waist section 113 upon inflation.
Upper bag section 111 engages occupant's torso and lower bag c section 112 engages the occupants legs and seat surface.
Inflated belt section 113 which has belt 116 engaging its outer surface positions belt 116 distance X from occupant's
(0) waistline. Bag sections 111, 112 engage at line L and with added forces during deceleration and inflation bag portions 111, 112 may be forced against one another. 10
Turning now to schematic Fig. 24a, bag sections 111, 112 are sized to form a ninety degree (90°) angle A between the torso and legs of occupant (O) . Fig. 24b shows bag 110' sized to form an angle of 105° or more when sections 111',
15 112' touch at point P. In Fig. 24c bag sections 111", 112" are of bag 110" are shown being distorted by forces applied by occupant (0) as sections 111", 112" compress. Volume V represents the volume of theoretical overlap of sections 111", 112" if no bag section compression occurred. The
20 volume or pressure of gases supplied to bag section 111" may differ from the volume or pressure of gases fed to the bag section 112" .
It is contemplated that the present invention may be used in aircraft, school buses, passenger cars and other 25 vehicles. In airplane applications having rows of seats, each row or portion should be equipped with a separate crash detector.
The present invention is particularly adaptable for use 30 in aircraft or other vehicles where lap belts have been in common use for many years. Bags can be deployed from the lap belt area without need for installation of equipment in the
17 seat backs located forward of the seated occupants. The invention provides protection for occupants, including pilots and passengers, of large or small aircraft.
In certain crashes of a large airplane in which the forward portion of the airplane may rapidly decelerate and come to rest while the rearward portion of the plane continues to decelerate, air bag deployment for effective occupant protection should occur in the forward part of the airplane before bag deployment occurs in the rearward portion of the plane. Commercial passenger planes with their long length are subject to a traveling crash wave within the plane. Where a crash involves the front of an aircraft striking a building, a mountain, the ground, or other object deceleration occurs in the forward part of the aircraft before it occurs in the rear of the aircraft. The points of rapid deceleration therefore move from front to back in a waveform. This waveform of deceleration requires that air bags in the front of the plane be deployed before air bags in the rear of the plane.
Turning to Fig. 25, three (3) rows of passengers are shown in which a forward row 124 is equipped with a gas supply unit 128 to serve that row. Gas supply unit 128 includes an initiator, an inflator and gas supply lines (not shown) which lines supply the bags mounted on the lap belts positioned across laps of the occupants in their seats. The inflator is sized to supply the air bags which serve each of the two (2) seats in row 124. Gas supply unit 128 also includes a crash detector or other arrangement for creating a crash signal when a selected deceleration occurs at row 124. The crash triggers the firing system creating a crash signal which in turn causes the initiator to ignite the inflator to rapidly create gases and supply them to the air bags in row 124. The air bags of forward row 124 are in a state of deployment in which the bags have been fully filled with gas and the passengers' torsos have swung forward.
Also shown in Fig. 25 is middle row 130 in which bag deployment has started and rearward row 132 in which the crash detector has not yet caused the air supply system to commerce operation.
Alternatively, a gas supply unit may be positioned adjacent each individual seat in each row. Each supply unit may have its own crash detector firing system and inflator. An alternative arrangement for sequentially initiating bag deployment in a large aircraft is to have a single crash detector serve more than one row of seats.
When a crash detector serves more than one row of seats the signal serving the more rearward rows is preferably delayed so that bag deployment occurs when it can provide maximum protection for each of the occupants in each row. Deployment is timed to occur sufficiently in advance of rapid deceleration of the occupants to allow for bag inflation to provide maximum protection from injury or death.
Turning to Fig. 26 crash detector 133 serves three rows of seats. Forward row 135 has four (4) seats 135a-d. Each seat has its own gas supply unit 136a-d. Middle row 138 with four (4) seats 138a-d has each of its seats served by a gas supply unit 139a-d and rearward row 141 with seats 141a-d have gas supply units 142a-d. Crash detector 133 supplies signals to each row along electrical conduits 144, 145 and 146. The signals transmitted along conduit 144 cause the start of initiator, followed by, inflator activation, immediately after detector 133 measures a sudden
19 deceleration. The signal transmitted along conduit 145 (which is simultaneously transmitted with the conduit signal) is delayed by time delay 148 so that bag deployment in middle row 138 occurs after row 135 deployment. The signal c transmitted along conduit 146, again simultaneously transmitted with the 144 conduit signal, is also delayed by time delay 149 so that rearward row 141 is deployed after middle row 138. An aircraft with forty (40) rows of seats would be equipped with a dozen or more crash detectors .
0
The crash detector and firing signal unit 133 includes a firing system 149 produces a low voltage (amperage) signal. The system is preferably battery powered.
Turning to Fig. 27, circuitry for a crash detector is 5 shown in which actuating lever 150 is moved with aircraft deceleration Lever 150 moves when deceleration in that section of the plane occurs to in turn move switch arms 151a,
152a of switch 151, 152 respectively. Prior to the occurrence of a crash, switch arms 151a, 152a engage the 0 upper stationary contact 151u, 152u of switches 151, 152 which short circuits capacitor 155 and resistor 156. Switch
152 also provides a short circuit across pyrotechnic squib
158. This prevents capacitor 155 from being charged and the squib 158 from being fired. In this pre-crash mode, the timing circuit 160 is powered by battery 161. 5
Upon a crash, actuating lever 150 moves switch arms 151a, 152a to their lower positions causing a voltage to be applied by battery 161 through diode 162 to start terminal
163 of timing circuit 160. Capacitor 50 becomes charged. 0
Timing circuit 160 times the preselected period. At the end of the period, the timing circuit 160 produces a series
20 of pulses on line 166. These pulses trigger the transistor 168 into a state of conductivity at the same frequency as the pulses. When the transistor 168 becomes conductive, a relatively low voltage is produced on the collector of the c transistor 168. This low voltage discharges the capacitor 155 and is introduced to the base of the transistor 170 to make the transistor 170 conductive. The pulses are filtered out by capacitor 155 as a result of the charging of the capacitor through a circuit including the battery 161, the switch 151 and the base/emitter junction of the transistor 0
170.
The flow of current through the transistor 170 causes a relatively high voltage to be produced across the resistor 156. This high voltage establishes a state of conductivity 5 in the transistor 156. When the transistor 156 becomes conductive, it has a relatively low impedance. This causes a circuit to be established through the capacitor 172, the switch 152 (in the second state of operation) , the pyrotechnic squib 158 and the transistor 176. The capacitor 0 172 then discharges through the pyrotechnic initiator 158 to fire the pyrotechnic initiator. The firing of the pyrotechnic initiator 158 initiates the operation of the inflator to inflate bags in a passenger row. U. S. Patent
No. 5,335,598 issued August 9, 1994 and owned by the assignee of the present application discloses and claims the timing 5 system including a timing circuit as described above. U. S.
Patent No. 5,335,598 is incorporated herein by reference.
The firing circuit 150 and initiator 158 may be housed in a single housing as disclosed and claimed in U.S. Patent 0 NO. 5,499,579 issued March 19, 1996 and owned by the assignee of the present invention. U.S. Patent No. 5,499,579 is incorporated herein by reference.
21 - The timing circuit 160 may utilize an input mechanism as the source of energy instead of a battery. An input electrical pulse, for example, of five (5) amperes and five (5) milliseconds, from an input mechanism is preferred rectified converting it to direct current which energy is stored in a capacitor as disclosed and claimed in U.S. Patent No. 5,507,230 issued April 16, 1996 and owned by the assignee of the present invention. U.S. Patent No. 5,507,230 is incorporated herein by reference.
Where electrical noise may trigger premature activation of the initiator, Faraday shielding may be placed around the firing circuit or internal filtering may be used or both. The triggering signal may be filtered by a low pass filter (e.g. inductance and capacitance) to prevent noise from passing. Finite filtering may also be employed. A device e . g. zener diode) limits the triggering signal amplitude. The filtered triggering signal charges the capacitance in the low pass filter. The capacitor charge causes a second transistor to become conductive, thereby producing a voltage across an impedance. This voltage triggers the first transistor to the conductive state to provide for the firing of the initiator.
Faraday shielding and filtering are further described in
U.S. Patent No. 5,440,991 issued August 15, 1995 and owned by the assignee of the present invention.
For another embodiment of the invention, the crash detector may be triggered by propagated energy waves such as radar waves rather than by aircraft deceleration. For example, a radar signal may be sent out by the airplane which signal would reflect off an object which is on a collision course with the airplane. The reflected signal would then
22 trigger the crash detector to start the sequence of inflation row by row of the occupants air bags prior to the collision. A computer may be used to compute the time of the deceleration in various vehicle portions. By starting the c inflation process, prior to collision, the time for deployment may be extended from twenty or forty milliseconds to 1000 milliseconds. For example, if an airplane traveling at 120 mph (176 ft. per second) and the bag is deployed when airplane is 176 ft from collision, a period of 1000 milliseconds may be provided for deployment to occur. Longer ° deployment times reduce the peak forces and pressure applied to passengers thus reducing the risk of injury by the bags during inflation.
The forces generated in the lap belts of the present 5 invention are about one thousand (1000) pounds per side. Gas bag pressure upon full inflation is about 20 psig. Inflation times are between 10 and 1000 milliseconds.
Inflatable members other than bags such as belts may be 0 useful in practicing the present invention. The embodiments of Figs. 25-27 are also useful in vehicles other than airplanes such as trains, buses and elongated automobiles.
Further such embodiments may employ the same inflators using the same pyrotechnic materials and propellants described herein. 5
0
23

Claims

I CLAIM :
1. A vehicle restraint system for restraining during rapid deceleration an occupant having a lap area, a waistline, a torso, a head, and legs comprising
a) a vehicle seat having a seating surface which vehicle seat is attached to the vehicle;
b) a lap belt;
c) anchor means attached to the vehicle for anchoring such lap belt;
d) the vehicle seating surface and the occupant's legs forming a lap area supporting surfaces;
e) an inflatable member mounted on such lap belt for restraint by such belt, such inflatable member having an inflatable envelope, in turn comprising
i) a plurality of exterior member surfaces; and
ii) a portion of the inflated member being positioned between the occupant's lap and such belt which portion has sufficient size to exert force against the occupant ' s lap area and waistline upon such inflation;
f) said inflatable member being sized and shaped when inflated so that one exterior member surface engages occupant ' s legs and another
24 exterior member surface engages occupant ' s torso to prevent substantial rotation of the torso during deceleration.
c 2. The vehicle restraint system of claim 1 in which the inflatable member includes a pressure envelope and has an interior belt -containing passageway which passageway is part of the bag pressure envelope.
3. The vehicle restraint system of claim 1 in which 0 the inflatable member includes a torso section, a waistline section and a leg section and in which the belt extends around such member and adjacent the waistline section upon member inflation.
5 4. The restraint system of claim 1 in which torso rotation during rapid deceleration is less than 10┬░.
5. The restraint system of claim 1 in which torso rotation during rapid deceleration is between 0┬░ and 45┬░. 0
6. The restraint system of claim 1 in which the lap area includes a substantial portion of the upper leg surface between the occupant's waistline and knees.
7. The restraint system of claim 1 in which the torso- 5 engaging exterior member surface engages the torso from the waistline to the occupant's head.
8. The restraint system of claim 1 in which the member also provides support portion for occupant's head. 0
9. The restraint system of claim 2 in which the inflatable member has an interior passageway sufficiently
25 large to permit sliding of the member on the lap belt from side to side along occupant's waistline to adjust the position of the member prior to inflation.
10. The restraint system of claim 2 in which the inflatable member has an interior passageway located spaced from the belt so that when the member inflates an inflated member portion between the lap belt and the occupant's waistline causes the occupant to be move away from the belt .
11. A vehicle restraint system comprising
a) a vehicle seat having a seating surface attached to the vehicle for an occupant having a lap, a torso and legs;
b) a lap belt having two ends;
c) anchor means attached to the vehicle for anchoring each lap belt end;
d) a bag having an inflatable envelope in turn comprising
i) an exterior bag surface; and
ii) an interior passageway with two portals in the bag body such portals are positioned and such interior passageway is sized to receive said belt such that;
e) said bag when inflated has a rear inflated portion between the lap belt and the occupant ' s lap and a forward inflated torso-
26 - supporting portion and leg engageable portion forward of the lap belt.
12. The vehicle restraint system of claim 11 m which c the bag further includes prior to the inflation a plurality of bag body areas stitched with a row of stitches to the inflatable bag envelope which rows of stitches fail at predetermined interior bag pressures with each bag body area as released by stitch failure and inflation providing a bag addition. 0
13. The vehicle restraint system of claim 11 m which a first bag body area is stitched with a first row of stitches and a second bag body area is stitched with a second row of stitches, the first row fails at a selected bag pressure and 5 the second row fails at a pressure higher than said selected pressure whereby the first bag body area deploys first as beg pressure rises to and above the selected bag pressure.
14. The vehicle restraint system of claim 11 m which 0 the bag when inflated has a rear surface of sufficient size to resist occupant ' s torso rotation and the bag when inflated has a lower surface of sufficient size to engage the occupant ' s legs and seating surface to prevent substantial rotation of the bag about the lap belt.
5
15. The vehicle restraint system of claim 11 m which such bag is positioned with the lap belt through the passageway and the remaining bag portions folded against the belt and encased in a rupturable sheath.
0 16. The vehicle restraint system of claim 11 m which the bag has a reinforcing material section attached to the bag pressure-retaining envelope adjacent the belt passageway.
27 -
17. The vehicle restraint system of claim 11 in which the bag pressure-retaining envelope includes in addition a blister portion and rupturable attachment means for attaching the blister to the envelope such that upon a threshold c pressure being reached blister portion attachment means ruptures from such envelope and the blister portion inflates to provide further occupant upper body support .
18. The vehicle restraint system of claim 17 in which the blister portion attachment means is stitching. 0
19. The vehicle restraint system of claim 17 in which the blister portion deploys to support the occupant's head.
20. A vehicle restraint system for restraining an 5 occupant comprising
1) vehicle seat for the occupant having a lap and a torso;
0 a lap belt having two belt sections and a releasable buckle for engaging the two sections across the occupant's lap;
a bag having an inflatable envelope in turn comprising 5 a. an exterior bag body; and
b. a passageway portion in the bag body which passageway portion is sized to 0 receive at least one belt section; and
28 - 4) the bag when inflated having a rear inflated portion between the lap belt and the occupant ' s lap to cause the occupant to move away from the lap belt.
21. The vehicle restraint system of claim 20 in which the central passageway portion is spaced from the bag body when the bag is inflated.
22. A method of restraining during rapid deceleration a vehicle occupant having a lap, a waistline, a torso, a head and legs comprising
providing in the vehicle a vehicle seat having a seating surface;
providing an anchored lap belt across the occupant;
mounting on the lap belt an inflatable member restraining such member when inflated has a plurality of exterior surfaces; and
sizing and shaping the member to include a waistline section so that when inflated the waistline section urges the occupant and lap belt apart and one member surface engages the seating surface and occupant's legs over a substantial area and another bag surface engages the torso over a substantial area.
23. The method of claim 22 having the additional step of providing means for deploying in sequence member additions comprising a plurality of member body areas stitched to the bag body by a row of stitches with each stitch row being
- 29 - subject to failure at differing pressures whereby as a larger occupant is restrained by the inflated member as rows of stitches fail sequentially as member pressure rises.
c 24. The method of claim 22 in which a member belt passage is positioned in the member in front of the waistline section which section inflates between the lap belt and the occupant and the rest of the member inflates forward of the belt.
0
25. The method of claim 22 in which the member is sized and shaped to engage a substantial portion of the occupant's legs between the hips and the knees and also to engage a substantial portion of the torso between the hips and neck.
5 26. A method of restraining an occupant having a lap and a torso in a vehicle seat upon rapid deceleration comprising
providing a seat secured to the vehicle, 0 installing the lap belt secured to the vehicle on either side and across the occupant;
providing an inflatable member having an envelopment including an outside envelopment 5 portion and an interior passageway portion including portals and a central section through the bag which passageway central section is spaced from the envelope to form when inflated a rear inflated bag portion and which bag includes when 0 inflated a forward torso supporting portion;
inflating the bag upon deceleration;
- 30 - whereby the passenger is urged away from the lap belt by the rear inflated bag portion and the forward inflated bag portion reduces any substantial occupant torso forward movement .
27. A vehicle restraint system for protecting a vehicle occupant comprising
a lap belt system positioned across the occupant's lap which lap belt system includes
a first belt section having first attachment means at one end and first anchor means at the other end;
a second belt section having second attachment means at one end and second anchor means at the other end;
an inflatable member mounted on the lap belt system;
means for detecting vehicle deceleration and producing gases to inflate the inflatable member positioned within the lap belt system in turn comprising
a) an initiator means for initiating operation of the inflation means;
b) inflation means mounted on the lap belt for producing gases;
31 c) crash detector means which means produces a signal to cause the initiator means to operate;
d) electrical conducting means for conducting the said signal from the crash detector means to the initiator means; and
e) conduit means for providing the flow of gases from the inflation means to the inflatable member.
28. The vehicle restraint system of claim 27 in which the first attachment means is a buckle and the second attachment means is a tongue unit for detachable engagement with the buckle.
29. The vehicle restraint system of claim 28 in which the inflatable member is connected to the tongue unit and which the inflation means is located in the tongue unit.
30. The vehicle restraint system of claim 28 in which the inflatable member is attached to the buckle, the inflation means is in the tongue unit and conduit means for providing flow of gases includes a first conduit section from the inflation means to tongue unit end surface, second conduit section in the buckle and connector means on the first and second conduit sections to provide a detachable connection between the buckle and tongue unit as the buckle and tongue unit are buckled and unbuckled.
31. The vehicle restraint system of claim 27 in which inflation means is located in an anchor means and the belt
32 section connected to such anchor means has a gas conduit therein to conduct gas to the inflatable member.
32. The vehicle restraint system of claim 27 in which c the electrical conducting means includes a first segment in the first attachment means and a second segment in the second attachment means and having connector means on the ends of such segments to provide for detachably connecting the segments when the first and second attachment means are connected and disconnected during operation of the system. 0
33. The vehicle restraint system of claim 1 having an inflator for inflating the inflatable member which inflator in turn comprises
5 a) a housing with walls having stored pressurized gas therein and having a quantity of pyrotechnic material spaced from the side walls;
0 b) the pyrotechnic material having burning characteristics such that it burns prior to particles reaching the side walls
whereby the inflator walls are not substantially heated by pyrotechnic material engaging such walls. 5
34. The vehicle restraint system of claim 33 in which the pyrotechnic material includes an oxidizer, a nitramine and a binder.
0 35. The vehicle restraint system of claim 33 in which the pyrotechnic material is a solvent processed propellant with microscopic fine porosity.
- 33
36. The vehicle restraint system of claim 33 in which the pyrotechnic material is a micropropellant with small granules having ultra-thin webs.
c
37. A vehicle restraint system for restraining during rapid deceleration occupants in a vehicle having a vehicle first and second portions in which deceleration occurs in the first portion prior to deceleration in the second portion and in which occupants are positioned in the first and second portions comprising 0
a) an inflatable member mounted to be deployed to protect the first occupant;
b) an inflatable member mounted to be deployed to 5 protect the second occupant;
c) inflation means for inflating said inflatable members ; and
0 d) control means for controlling the inflation means so that the first member inflates prior to the second member.
38. The vehicle restraint system of claim 37 in which occupants are positioned in a row of seats in the first 5 vehicle portion and in which occupants are positioned in a row of seats in the second vehicle portion.
39. The vehicle restraint system of claim 38 in which the control means includes a crash detector for each row of 0 seats.
- 34
40. The vehicle restraint system of claim 37 in which the control means includes a crash detector, electrical conduits and time delay means.
c 41. The vehicle restraint system of claim 37 in which the vehicle is an airplane.
42. The vehicle restraint system of claim 37 in which the vehicle is a bus.
0
43. The vehicle restraint system of claim 37 in which the vehicle is a train.
44. The vehicle restraint system of claim 37 in which the vehicle is an automobile. 5
45. A method of restraining occupants in a vehicle during rapid deceleration in a vehicle having vehicle first and second portions for which deceleration occurs in the first portion prior to deceleration in the second portion 0
1) providing occupant seats in the first and second portions;
2) positioning an inflatable member mounted to be deployed for protecting occupants in such 5 occupant seats;
3) providing inflation means to serve each inflatable member;
0 4) providing deceleration detection means; and
35 - 5) providing control means for actuating the inflation means in the first and second portions to provide for timely deployment of the inflatable members.
46. The method of restraining occupants in a vehicle of claim 45 in which the deceleration detection means produces signals which deploy inflatable members in the first vehicle portion before such signals causes deployment in the second vehicle portion.
47. The method of restraining occupants of claim 45 in which the deceleration detection means produces a signal upon deceleration of the first portion of the vehicle which signal causes deployment of inflatable member in the first portion and which signal after a predetermined time delay causes deployment of the inflatable member in the second portion.
48. The method of restraining occupants of claim 45 in which a row of seats is provided in each of the first and second vehicle portions and in which the deceleration detection means detects the deceleration for each such row.
49. The method of restraining occupants of claim 47 in which the deceleration detection means provides a signal for each row of seats which signal causes inflation member deployment in such row.
50. The method of restraining occupants of claim 45 in which the deceleration detection means in turn comprises means for detecting the collision of a vehicle with an object prior to the collision, means for computing the amount of deceleration and time of deceleration that will occur in such vehicle portions.
36
51. The method of restraining occupants of claim 50 in which such deceleration detection means provides signals to the inflatable member in the vehicle portions to cause inflation to protect the occupant when the deceleration in such portion requires inflation to protect the occupants.
37
PCT/US1999/004561 1998-03-03 1999-03-02 Lap mounted inflatable bag and method of use WO1999044865A1 (en)

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KR1020007009761A KR20010041573A (en) 1998-03-03 1999-03-02 Lap mounted inflatable bag and method of use
AU29774/99A AU2977499A (en) 1998-03-03 1999-03-02 Lap mounted inflatable bag and method of use
BR9908471-6A BR9908471A (en) 1998-03-03 1999-03-02 Vehicle restraint system and process to contain a vehicle occupant during rapid deceleration
EP99911037A EP1060095A1 (en) 1998-03-03 1999-03-02 Lap mounted inflatable bag and method of use
JP2000534436A JP2002505226A (en) 1998-03-03 1999-03-02 Inflatable bag provided in wrap portion and method of using the same

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US09/033,739 1998-03-03
US09/033,739 US6293582B1 (en) 1996-06-14 1998-03-03 Control system for air bags in different vehicle locations

Publications (1)

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WO1999044865A1 true WO1999044865A1 (en) 1999-09-10

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US (2) US6293582B1 (en)
EP (1) EP1060095A1 (en)
JP (1) JP2002505226A (en)
KR (1) KR20010041573A (en)
AU (1) AU2977499A (en)
BR (1) BR9908471A (en)
WO (1) WO1999044865A1 (en)

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WO2003072401A1 (en) * 2002-02-26 2003-09-04 Dalphi Metal España, S.A. Seat belt with built-in airbag for vehicles
GB2390339A (en) * 2002-07-03 2004-01-07 Autoliv Dev Seat belt mounted airbag
GB2390338A (en) * 2002-07-03 2004-01-07 Autoliv Dev Airbag to be mounted on the lap strap of a seat belt
GB2390339B (en) * 2002-07-03 2005-10-12 Autoliv Dev Improvements in or relating to an air-bag
GB2390338B (en) * 2002-07-03 2005-11-02 Autoliv Dev Improvements in or relating to an air-bag
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EP2933191A1 (en) * 2014-04-15 2015-10-21 Airbus Operations GmbH Seat belt arrangement and seat assembly incorporating same
US10279914B2 (en) 2014-04-15 2019-05-07 Airbus Operations Gmbh Seat belt arrangement and seat assembly incorporating same
US20210300277A1 (en) * 2020-03-30 2021-09-30 Toyoda Gosei Co., Ltd. Occupant protection device
US11498505B2 (en) * 2020-03-30 2022-11-15 Toyoda Gosei Co., Ltd. Occupant protection device
US20210300278A1 (en) * 2020-03-31 2021-09-30 Toyoda Gosei Co., Ltd. Occupant protection device
US11603063B2 (en) * 2020-03-31 2023-03-14 Toyoda Gosei Co., Ltd. Occupant protection device

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JP2002505226A (en) 2002-02-19
BR9908471A (en) 2000-12-05
KR20010041573A (en) 2001-05-25
AU2977499A (en) 1999-09-20
US20020011723A1 (en) 2002-01-31
US6293582B1 (en) 2001-09-25
EP1060095A1 (en) 2000-12-20

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