WO2013018781A1 - Curtain airbag - Google Patents

Curtain airbag Download PDF

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Publication number
WO2013018781A1
WO2013018781A1 PCT/JP2012/069384 JP2012069384W WO2013018781A1 WO 2013018781 A1 WO2013018781 A1 WO 2013018781A1 JP 2012069384 W JP2012069384 W JP 2012069384W WO 2013018781 A1 WO2013018781 A1 WO 2013018781A1
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WIPO (PCT)
Prior art keywords
curtain airbag
vehicle
chamber
gas
front chamber
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Application number
PCT/JP2012/069384
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French (fr)
Japanese (ja)
Inventor
有馬 隆
Original Assignee
オートリブ ディベロップメント エービー
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Priority to JP2013526925A priority Critical patent/JP5646060B2/en
Publication of WO2013018781A1 publication Critical patent/WO2013018781A1/en

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    • 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
    • B60R21/23Inflatable members
    • B60R21/231Inflatable members characterised by their shape, construction or spatial configuration
    • B60R21/232Curtain-type airbags deploying mainly in a vertical direction from their top edge

Definitions

  • the present invention relates to a curtain airbag that inflates and deploys along a side surface of a vehicle interior for the purpose of protecting an occupant at the time of a vehicle side collision or rollover (rollover).
  • the curtain airbag is an airbag that is installed above the side door in the vehicle interior and inflates and deploys along the side window of the vehicle when an impact occurs.
  • Patent Literature 1 describes a curtain airbag that is considered so as to accurately protect a passenger during a rollover.
  • This curtain airbag has a lower inflating portion extending in the vehicle front-rear direction on the lower edge side, and since this lower inflating portion is supported by the center pillar, it is said that the movement of the occupant outside the vehicle can be suppressed. Yes.
  • the lower inflating portion is provided in a wide area over the entire length of the curtain airbag in the vehicle front-rear direction, and a second inflator is necessary to inflate the lower inflating portion. It has become.
  • a simpler and lighter configuration is desired for current vehicles. By focusing on the area where the passenger is likely to be released from the vehicle, it is considered that a curtain airbag having a more simple configuration than the curtain airbag disclosed in Patent Document 1 and having a high ability to prevent release from the vehicle can be realized.
  • the present invention has been made in view of such a problem, and an object of the present invention is to provide a curtain airbag capable of further improving the performance of preventing the release from the vehicle with a simple configuration.
  • the inventors diligently studied the above problem and found that the front-end chamber in the longitudinal direction of the vehicle in the divided expansion region called the chamber is less likely to be tensioned than the central chamber.
  • This front end chamber (front chamber) has no other chamber in front of itself, and is less likely to receive support from surrounding parts than the central chamber.
  • This front chamber is an effective part for catching an occupant whose posture has been largely lost during rollover, and is an important chamber for improving the anti-release performance of the curtain airbag.
  • a typical configuration of a curtain airbag according to the present invention is a curtain airbag that is housed above a side surface in a vehicle compartment and inflates and deploys along the side surface.
  • a front chamber that is partitioned at the foremost in the vehicle front-rear direction among the chambers in which gas flows and expands, and has a front chamber having an overlap portion that expands on the door trim, and an overlap portion from the center in the vehicle front-rear direction
  • a gas inflow passage extending toward the door trim and extending at least partially overlapping the center pillar.
  • the gas inflow path is also arrange
  • the center pillar is a portion that protrudes to the innermost side among the side surface portions in the vehicle interior.
  • the curtain airbag is inflated and deployed along the portion where the outside of the vehicle is supported by the center pillar and the door trim from the gas inflow path to the front chamber. Therefore, the curtain airbag is less likely to jump out of the vehicle even if the side window is open, and can be located closer to the inside of the vehicle, that is, closer to the occupant from the beginning of inflation and deployment.
  • since the outer side of the vehicle is supported by the door trim, it is possible to efficiently absorb the load from the occupant, and it is possible to suitably suppress the occupant's release amount from the vehicle.
  • the entrance of the above gas inflow passage should overlap the center pillar.
  • the gas inflow path can be located more on the vehicle inner side from the beginning of the expansion and deployment. Therefore, it is possible to contact the occupant at an early stage and efficiently reduce the amount of release outside the vehicle.
  • the gas inflow path may have a narrowest portion having the smallest diameter among all the gas paths in the curtain airbag at a predetermined position. By having the narrowest part with such a small diameter, it becomes difficult for gas to flow out from the gas inflow path. Therefore, the gas inflow path and the front chamber can maintain a high gas pressure, and the shock absorption performance and the vehicle outside discharge prevention performance are improved.
  • the above-described front chamber and gas inflow path may be integrated without being partitioned from each other. If the front chamber and the gas inflow passage are provided with a boundary, the boundary becomes constricted after inflating and deploying, and there is a possibility that the impact absorbing power or the like may be reduced due to a break when the occupant is received. Therefore, in the above configuration, the front chamber and the gas inflow path are set to inflate and deploy as a single chamber as a whole, thereby improving the shock absorption performance and further the outside release prevention performance.
  • the front chamber may be formed so that gas flows from the overlap portion toward the top of the curtain airbag. In this manner, by starting expansion and deployment from the overlap portion supported by the door trim, it is possible to improve the impact absorption performance of the front chamber. Moreover, the upper part of the normal curtain airbag is fixed to the vehicle by a fastening member or the like. Since the upper part is fixed to the vehicle, it is difficult for the rocking to occur. Therefore, the front chamber suppresses the rocking by allowing the gas to flow upward.
  • the front chamber may be provided in a portion that protects the spot position at the forefront of the vehicle among a plurality of spot positions of an impactor that is a test device in the vehicle discharge prevention performance evaluation test.
  • the portion of the general curtain airbag that covers the hitting position at the forefront of the vehicle is not supported by the surroundings because there is no other chamber ahead of it, and the tension tends to decrease.
  • the front chamber having the above-described configuration, it is possible to suitably protect the spot position at the forefront of the vehicle with high impact absorption performance and the like.
  • the overlap portion is provided so as to be positioned below at least a plurality of hit points. With this configuration, the overlap portion absorbs a load from each hitting point position and can more favorably support the front chamber.
  • the curtain airbag is disposed behind the front chamber and on the side of the seat, and the main chamber into which gas flows in at the beginning of the inflation and deployment of the curtain airbag, and the front and back of the predetermined area of the curtain airbag. It is preferable to further include a first seam portion that is formed by bonding or integrating the cloth and guides the gas from the main chamber toward the gas inflow path.
  • the main chamber described above it is possible to quickly protect an occupant in the normal seating position. Further, the first seam portion causes expansion and deployment to proceed in a flow from the main chamber to the front chamber via the gas inflow path.
  • the front chamber often comes into contact with an occupant whose posture has been lost, and is particularly a part that is expected to be effective during a rollover in which the occupant easily loses its posture.
  • Rollover is a phenomenon that occurs following a side collision and the like, and a slight time difference occurs between the occurrence of the rollover and the first impact. Therefore, if the front chamber is inflated and deployed following the main chamber as described above, it is possible to suitably protect the occupant corresponding to both the first side collision and the subsequent rollover. It becomes possible.
  • the above-mentioned front chamber may be a delay chamber that completes expansion and deployment behind the main chamber.
  • the front chamber can suitably cope with a rollover that occurs following the first side collision or the like.
  • the above-mentioned main chamber may have a second seam portion formed by joining or integrating the base fabrics on the front and back sides of a predetermined region to suppress the thickness of the main chamber after expansion and deployment.
  • a predetermined thickness By suppressing the main chamber to a predetermined thickness, it is possible to reduce the possibility that the main chamber is excessively expanded and deviated from the target position. Further, by reducing the gas capacity, it becomes possible to speed up the gas supply to the front chamber.
  • FIG. 3 is a cross-sectional view taken along line AA in FIG. 2.
  • FIG. 3 is a sectional view taken along line BB in FIG. It is a figure which illustrates the curtain airbag concerning 2nd Embodiment of this invention.
  • D1 Outlet diameter
  • D2 Inlet diameter
  • 100/200 Air bag, 102 ... Inflator, 104 ... Tab, 106 ... Roof side rail, 108 ... Vehicle, 109 ... Door, 110 ... Side window, 112 ... 1st seam portion, 114 ⁇ 202 ... main chamber, 116 ... front seat, 118 ... path, 120 ⁇ 206 ... gas inflow passage, 120a ⁇ 206a ... inlet, 122 ... front chamber, 122a ... overlap portion, 124 ... Center pillar, 126 ... Door trim, 204 ... Second seam, 206b ... Outlet
  • FIG. 1 is a diagram illustrating a curtain airbag according to the first embodiment of the present invention.
  • FIG. 1 illustrates a curtain airbag (hereinafter referred to as an airbag 100) in an inflated and deployed state.
  • an airbag 100 a curtain airbag
  • description will be made with reference to the airbag 100 for the right side surface of the vehicle interior illustrated in FIG. 1, but the airbag for the left side surface has a similar symmetrical structure.
  • the airbag 100 is formed in a bag shape by, for example, a method of sewing from a total of two base fabrics constituting the front and back surfaces, a method of spinning using OPW (One-Piece Woven), or the like.
  • the airbag 100 includes an inflator 102 that is a gas generator, and the airbag 100 is inflated by the pressure of gas supplied from the inflator 102 to restrain an occupant.
  • a plurality of tabs 104 are provided on the upper edge of the airbag 100 as parts for attachment to the vehicle 108 (see FIG. 2).
  • the tab 104 is formed in a band shape, and the tab 104 is fixed to the vehicle 108 by using a bolt or the like.
  • FIG. 2 is a diagram illustrating the curtain airbag shown in FIG. 1 attached to the vehicle 108.
  • the airbag 100 is attached to the roof side rail 106 above the side surface in the vehicle compartment in a wound state or a folded state. At that time, since the airbag 100 is housed inside the roof trim, the airbag 100 is not visible from the passenger compartment.
  • a sensor (not shown) provided in the vehicle 108 first detects the impact, and an ignition signal is transmitted to the inflator 102 due to this. Then, the explosive in the inflator 102 burns and the generated gas is supplied into the airbag 100. With this gas, the airbag 100 is inflated and deployed downward along the side window 110 and the like to protect the occupant.
  • the inflatable region of the airbag 100 is partitioned into a plurality of small rooms (chambers) in consideration of the seat position and the like.
  • the respective chambers provided in the airbag 100 will be described in detail with reference to FIGS. 1 and 2.
  • the gas is guided by the first seam portion 112 to a region in front of the vehicle from the inflator 102.
  • the first seam portion 112 is a portion where base fabrics on the front and back sides of a predetermined region of the airbag 100 are joined or integrated.
  • the airbag 100 is a so-called center fill type in which the inflator 102 is provided near the center in the vehicle front-rear direction, and the first seam portion 112 is formed so as to guide gas from below the inflator 102 to the front of the vehicle.
  • First main seam 114 is inflated and deployed by the first seam portion 112 on the front side of the vehicle.
  • the main chamber 114 is disposed on the side of a front seat (not shown), and mainly protects the head of an occupant at a normal seating position in the front seat.
  • FIG. 2 illustrates nine dots indicated by symbols A1 to A4, B1 to B4, and C1.
  • These impact points are impactors (not shown) that are test equipment in the external vehicle emission prevention performance evaluation test defined by FMVSS 226 (Federal Automobile Safety Standards) Section 5.2: Determination impact target locations. ) Is the hit position of the collision.
  • FMVSS 226 does not have names such as A1 to A4, B1 to B4, and C1 for these hit points, but each hit point position is the primary target in the front side window and rear side window (all side windows in the second and subsequent rows). It matches the target position determined by the position (Primary (target) and the secondary target position (Secondary target), and the target position obtained by reconfiguring them.
  • hitting point positions in the present embodiment are set based on the opening area of the door 109, that is, the range of the side window 110 or the like.
  • the impactor is caused to collide with each hit point on the airbag 100, and the release amount of the airbag 100 outside the vehicle is measured.
  • the main chamber 114 mainly protects A2 to A4 hit points among the plurality of hit points.
  • the gas flowing into the main chamber 114 is guided to the gas inflow path 120 through a path 118 formed below the first seam portion 112.
  • the gas inflow passage 120 is a passage that guides gas to the front chamber 122 that is partitioned in front of the airbag 100.
  • the airbag 100 has a configuration in which the anti-release performance in the front chamber 122 is improved.
  • the specific configuration and operation will be described in detail below.
  • the gas inflow passage 120 that supplies gas to the front chamber 122 is disposed so as to overlap the center pillar 124 and the door trim 126.
  • the gas inflow path 120 is set so that the position of the inflow port 120 a that is the gas inlet overlaps the center pillar 124.
  • FIG. 3 is a cross-sectional view taken along the line AA in FIG.
  • the gas inflow path 120 starts to expand from the inlet 120 a on the center pillar 124, and further expands along the door trim 126 to guide the gas to the front chamber 122.
  • the center pillar 124 is a portion that protrudes to the innermost side among the side portions of the vehicle interior including the side window 110 and the like.
  • the door trim 126 also projects from the side window 110 to the inside of the vehicle. That is, the gas inflow path 120 extends from the vehicle center side toward the front chamber 122 along a region that protrudes further toward the inside of the vehicle.
  • the gas inflow path 120 is connected to an overlap portion 122 a that is a lower portion of the front chamber 122.
  • the overlap portion 122 a is a portion that overlaps with the door trim 126 and expands.
  • the front chamber 122 starts expansion
  • FIG. 4 is a cross-sectional view taken along the line BB in FIG.
  • the front chamber 122 is inflated from an overlap portion 122 a that overlaps the door trim 126, so that the front chamber 122 is positioned closer to the inside of the vehicle, that is, closer to the occupant from the beginning of the inflated deployment, and thus comes into early contact with the occupant. It is possible to do.
  • the front side of the front chamber 122 is supported by the door trim 126, it is also possible to efficiently absorb the load from the occupant and suppress the amount of discharge outside the vehicle. Further, the front chamber 122 is less likely to jump out of the vehicle even when, for example, the side window 110 is open or when the door 109 is deformed toward the vehicle interior due to a side collision.
  • the front chamber 122 is formed so that gas flows from the overlap portion 122a toward the upper portion of the airbag 100.
  • the upper portion of the airbag 100 is fixed to the roof side rail 106 by the tab 104, and is less likely to swing. Therefore, the front chamber 122 is restrained from swinging that may occur during inflation and deployment by flowing gas toward the upper portion of the airbag 100.
  • the front chamber 122 and the gas inflow path 120 are integrated with each other without being partitioned from each other.
  • a seam joint portion such as a seam
  • a constriction occurs after inflation and deployment, and a fold occurs when the occupant is received.
  • the shock absorbing ability and the like are reduced. Therefore, in the present embodiment, the front chamber 122 and the gas inflow path 120 are set so as to expand and deploy as a single chamber as a whole, thereby improving the shock absorption performance and further the out-of-vehicle discharge prevention performance.
  • the inflow port 120 a is the narrowest part having the smallest diameter among the gas paths in the airbag 100.
  • the “gas path” is an expansion region that is mainly divided by seams, and the “diameter” is the distance from one point on one seam to the other seam in the vicinity. That is. Specifically, the diameter is measured by placing a compass core at a predetermined position on one seam, drawing a circle with the radius gradually increasing around it, and contacting the other seam for the first time. The radius of the circle at that time is the diameter in the gas path.
  • the inlet 120a (narrowest portion) has the smallest diameter, and this configuration makes it difficult for the gas to flow out from the gas inflow path 120. Therefore, the gas inflow path 120 and the front chamber 122 can maintain a high gas pressure, and the shock absorption performance and the vehicle outside discharge prevention performance are improved.
  • the airbag 100 is configured to inflate and deploy from the gas inflow path 120 to the front chamber 122 along the portion where the outside of the vehicle is supported by the center pillar 124 and the door trim 126.
  • the airbag 100 can exhibit high impact absorption performance and out-of-vehicle discharge prevention performance with a simple configuration.
  • the position of the A1 hit point illustrated in FIG. 2 is protected using the front chamber 122 described above.
  • This A1 hit point is the hit point position in front of the vehicle.
  • the portion that protects the A1 hitting point on the curtain airbag is not supported by the surroundings because there is no other chamber ahead of it, and the tension tends to decrease.
  • the front chamber 122 of the airbag 100 it is possible to suitably protect the A1 hit point with high impact absorption performance and the like.
  • the overlap portion 122a of the front chamber 122 is provided so as to be positioned below at least a plurality of hit points. Specifically, the overlap part 122a is located below the A2 hit point located in the lower row. With this configuration, it is possible to absorb the load from each hit point position using the overlap portion 122a and more favorably support the front chamber 122, the main chamber 114, and the like.
  • the airbag 100 inflation and deployment proceed in the order from the main chamber 114 to the front chamber 122 due to the gas flow through the first seam portion 112 and the gas inflow path 120.
  • the front chamber 122 is set as a delay chamber that completes the expansion and deployment behind the main chamber 114.
  • the front chamber 122 is often a part that is in contact with an occupant whose posture has been lost, and is particularly expected to be effective during a rollover.
  • Rollover is a phenomenon that occurs after a side collision or the like, and its occurrence has a slight time difference from the detection of the first impact. Therefore, if the front chamber 122 is inflated and deployed following the main chamber 114 as described above, the main chamber 114 quickly protects the occupant at the normal seating position at the time of a side collision, and the posture at the subsequent rollover. A passenger who breaks down can be protected by the front chamber 122. Thus, the airbag 100 can appropriately cope with both the side collision and the rollover.
  • FIG. 4 is a diagram illustrating a curtain airbag according to the second embodiment of the present invention.
  • the curtain airbag (hereinafter referred to as an airbag 200) is different from the airbag 100 of the first embodiment in terms of the configuration of a seam portion and the like.
  • the second seam portion 204 is provided in the main chamber 202.
  • the second seam portion 204 has a structure in which base fabrics on the front and back sides of a predetermined region of the main chamber 202 are joined or integrated, and the thickness of the main chamber 202 after expansion and deployment can be suppressed. By suppressing the main chamber 202 to a predetermined thickness in this way, the possibility that the main chamber 202 will be excessively expanded and deviated from the target position is reduced. Further, by providing the second seam portion 204, for example, the progress of the inflation and deployment of the airbag 200 can be arbitrarily set, for example, the gas capacity of the main chamber 202 is reduced and the gas supply to the front chamber 122 is accelerated. It becomes possible.
  • the diameter D1 of the outlet 206b in the gas inflow path 206 of the airbag 200 is set to be smaller than the diameter D2 of the inlet 206a (D1 ⁇ D2).
  • the outflow port 206b is the narrowest narrowest portion of all the gas paths of the airbag 200 and is the smallest diameter portion of all the gas paths.
  • the front chamber 122 can suppress the outflow amount of gas and can maintain the internal pressure high.
  • the amount of gas supplied to the front chamber 122 per unit time is limited, and the expansion completion time of the front chamber 122 can be delayed in accordance with the occurrence of rollover.
  • the gas inflow path 206 can arbitrarily set the expansion completion time of the front chamber 122 by arbitrarily setting the magnitude relationship between the inflow port 206a and the outflow port.
  • the present invention can be used for a curtain airbag that inflates and deploys along a side surface of a vehicle interior for the purpose of protecting an occupant during a vehicle side collision or rollover (rollover).

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  • Mechanical Engineering (AREA)
  • Air Bags (AREA)

Abstract

[Problem] To provide a curtain airbag which, using a simple configuration, can achieve improved performance of preventing a vehicle occupant from being thrown out of the vehicle. [Solution] A curtain airbag (100) is housed in the upper part of a side surface section of a vehicle interior and is inflated and expanded along the side surface section. The curtain airbag (100) is characterized by comprising: a front chamber (122) which, among the chambers inflated by gas flowing therein, is the chamber defined at the front-most position in the front-rear direction of the vehicle and which has an overlap section (122a) inflated while being overlapped on a door trim (126); and a gas inflow path (120) which extends from the center side in the front-rear direction of the vehicle toward the overlap section (122a) while overlapping the door trim (126) and which is disposed in such a manner that at least a part thereof overlaps the center pillar (124).

Description

カーテンエアバッグCurtain airbag
 本発明は、車両の側面衝突時やロールオーバ(横転)時に、乗員保護を目的として車室内の側面部に沿って膨張展開するカーテンエアバッグに関するものである。 The present invention relates to a curtain airbag that inflates and deploys along a side surface of a vehicle interior for the purpose of protecting an occupant at the time of a vehicle side collision or rollover (rollover).
 近年、車両には高い安全性が求められている。この傾向は世界各国に共通していて、現在では世界各国でエアバッグが車両の安全装置としてほぼ標準装備されている。そして、車両開発に関係する事業者ではさらなる安全性向上が重要な開発テーマとして掲げられていて、これに伴って日々新たなエアバッグが開発されている。 In recent years, vehicles are required to have high safety. This tendency is common in all countries of the world, and at present, airbags are almost standard equipment as vehicle safety devices in all over the world. Further, in business operators related to vehicle development, further improvement of safety is listed as an important development theme, and new airbags are being developed every day accordingly.
 車両の安全性の評価基準は各国において異なっていて、各事業者は製造品が多国の評価基準に対応し得るよう開発を行っている。例えば世界最大の自動車保有台数をほこる米国では、米国高速道路交通安全局(NHTSA)によって米国連邦自動車安全基準(FMVSS)が制定されている。そして現在、NHTSAが定めるFMVSS226には「側突時・ロールオーバ(横転)時において、放出緩和システムによりサイドウィンドウを通した乗員の車外放出の見込みを減少させる」という主旨の内容要件が提案されている。この要件は、放出緩和システムを構成する車外放出軽減対策装置として、カーテンエアバッグを備えることで達成可能である。 評 価 Vehicle safety evaluation standards differ from country to country, and each company is developing products that can meet multi-country evaluation standards. For example, in the United States, which has the largest number of vehicles in the world, the Federal Motor Vehicle Safety Standard (FMVSS) has been established by the National Highway Traffic Safety Administration (NHTSA). Currently, the FMVSS 226 established by NHTSA proposes a content requirement of “to reduce the possibility of passengers to be released from the vehicle through the side window by a release mitigation system in the event of a side collision / rollover”. Yes. This requirement can be achieved by providing a curtain airbag as an off-vehicle emission reduction countermeasure device constituting the emission mitigation system.
 カーテンエアバッグは、車室内のサイドドアの上方に設置されていて、衝撃発生時に車両のサイドウィンドウに沿って膨張展開するエアバッグである。例えば特許文献1には、ロールオーバ時における乗員の保護が的確に行えるよう考慮されたカーテンエアバッグが記載されている。このカーテンエアバッグは下縁側に車両前後方向へ伸びた下側膨張部を備えていて、この下側膨張部がセンタピラーによって支えられるために乗員の車外への移動を抑えることができるとされている。 The curtain airbag is an airbag that is installed above the side door in the vehicle interior and inflates and deploys along the side window of the vehicle when an impact occurs. For example, Patent Literature 1 describes a curtain airbag that is considered so as to accurately protect a passenger during a rollover. This curtain airbag has a lower inflating portion extending in the vehicle front-rear direction on the lower edge side, and since this lower inflating portion is supported by the center pillar, it is said that the movement of the occupant outside the vehicle can be suppressed. Yes.
特開2004-148976号公報JP 2004-148976 A
 特許文献1のカーテンエアバッグでは、下側膨張部はカーテンエアバッグの車両前後方向の全長にわたった広い領域に設けられていて、この下側膨張部を膨張させるために第2のインフレータが必要となっている。しかし、現在の車両にはより簡潔で軽量な構成が望まれている。乗員の車外放出が発生しやすい領域に焦点を当てることで、特許文献1のカーテンエアバッグよりも簡潔な構成で車外放出防止性能の高いカーテンエアバッグが実現できると考えられる。 In the curtain airbag of Patent Document 1, the lower inflating portion is provided in a wide area over the entire length of the curtain airbag in the vehicle front-rear direction, and a second inflator is necessary to inflate the lower inflating portion. It has become. However, a simpler and lighter configuration is desired for current vehicles. By focusing on the area where the passenger is likely to be released from the vehicle, it is considered that a curtain airbag having a more simple configuration than the curtain airbag disclosed in Patent Document 1 and having a high ability to prevent release from the vehicle can be realized.
 本発明は、このような課題に鑑み、簡潔な構成でさらなる車外放出防止性能の向上が可能なカーテンエアバッグを提供することを目的としている。 The present invention has been made in view of such a problem, and an object of the present invention is to provide a curtain airbag capable of further improving the performance of preventing the release from the vehicle with a simple configuration.
 上記課題について発明者らは鋭意検討し、チャンバと呼ばれる区分けされた膨張領域のうち、車両前後方向の前端のチャンバが中央側のチャンバに比べて張力がかかりにくいことを発見した。この前端のチャンバ(フロントチャンバ)は、自体の前方に他のチャンバが存在しておらず、中央側のチャンバに比べて周囲の部位からの支持を受けにくい。このフロントチャンバはロールオーバ時に姿勢を大きく崩した乗員を受け止めるために有効な部位であり、カーテンエアバッグの車外放出防止性能を向上させるためには重要なチャンバである。 The inventors diligently studied the above problem and found that the front-end chamber in the longitudinal direction of the vehicle in the divided expansion region called the chamber is less likely to be tensioned than the central chamber. This front end chamber (front chamber) has no other chamber in front of itself, and is less likely to receive support from surrounding parts than the central chamber. This front chamber is an effective part for catching an occupant whose posture has been largely lost during rollover, and is an important chamber for improving the anti-release performance of the curtain airbag.
 以上のことから、上記課題を解決するために、本発明にかかるカーテンエアバッグの代表的な構成は、車室内の側面部上方に収納され、側面部に沿って膨張展開するカーテンエアバッグにおいて、ガスが流入して膨張するチャンバのうち車両前後方向の最前に区画されるフロントチャンバであって、ドアトリムに重なって膨張するオーバラップ部を有するフロントチャンバと、車両前後方向の中央側からオーバラップ部へ向かってドアトリムに重なって伸びるガス流入路であって、少なくとも一部がセンタピラーに重なって配置されているガス流入路と、を備えることを特徴とする。 From the above, in order to solve the above problems, a typical configuration of a curtain airbag according to the present invention is a curtain airbag that is housed above a side surface in a vehicle compartment and inflates and deploys along the side surface. A front chamber that is partitioned at the foremost in the vehicle front-rear direction among the chambers in which gas flows and expands, and has a front chamber having an overlap portion that expands on the door trim, and an overlap portion from the center in the vehicle front-rear direction A gas inflow passage extending toward the door trim and extending at least partially overlapping the center pillar.
 上記のガス流入路によって、フロントチャンバはドアトリムに重なっているオーバラップ部から膨張を開始する。また上記構成では、ガス流入路もまたドアトリムおよびセンタピラーへ重なる位置に配置されている。特にセンタピラーは、車室内の側面部のうち最も車内側へ突出している部位である。これらによって、当該カーテンエアバッグは、ガス流入路からフロントチャンバにかけて、車外側がセンタピラーおよびドアトリムによって支えられている部位に沿って膨張展開する。そのため、当該カーテンエアバッグは、例えサイドウィンドウが開口状態であっても車外へ飛び出してしまうおそれは低く、また膨張展開の当初からより車内側すなわち乗員の近くへ位置することができる。加えて、車外側がドアトリムに支えられているため乗員からの荷重も効率よく吸収することが可能であり、乗員の車外放出量を好適に抑えることが可能である。 ∙ The front chamber starts to expand from the overlapped part that overlaps the door trim by the gas inflow path. Moreover, in the said structure, the gas inflow path is also arrange | positioned in the position which overlaps with a door trim and a center pillar. In particular, the center pillar is a portion that protrudes to the innermost side among the side surface portions in the vehicle interior. As a result, the curtain airbag is inflated and deployed along the portion where the outside of the vehicle is supported by the center pillar and the door trim from the gas inflow path to the front chamber. Therefore, the curtain airbag is less likely to jump out of the vehicle even if the side window is open, and can be located closer to the inside of the vehicle, that is, closer to the occupant from the beginning of inflation and deployment. In addition, since the outer side of the vehicle is supported by the door trim, it is possible to efficiently absorb the load from the occupant, and it is possible to suitably suppress the occupant's release amount from the vehicle.
 上記のガス流入路の入り口は、センタピラーに重なっているとよい。この構成によって、ガス流入路は膨張展開の開始当初からより車内側に位置することができる。したがって、乗員と早期に接触し、その車外放出量を効率よく抑えることが可能になる。 ¡The entrance of the above gas inflow passage should overlap the center pillar. With this configuration, the gas inflow path can be located more on the vehicle inner side from the beginning of the expansion and deployment. Therefore, it is possible to contact the occupant at an early stage and efficiently reduce the amount of release outside the vehicle.
 上記のガス流入路は、所定の位置に、当該カーテンエアバッグ内のすべてのガスの経路のうち最も径が小さい最狭部を有するとよい。このような径の小さい最狭部を有することで、ガス流入路からガスが流出しにくくなる。したがって、ガス流入路およびフロントチャンバはガス圧を高く維持することが可能になり、衝撃吸収性能および車外放出防止性能が向上する。 The gas inflow path may have a narrowest portion having the smallest diameter among all the gas paths in the curtain airbag at a predetermined position. By having the narrowest part with such a small diameter, it becomes difficult for gas to flow out from the gas inflow path. Therefore, the gas inflow path and the front chamber can maintain a high gas pressure, and the shock absorption performance and the vehicle outside discharge prevention performance are improved.
 上記のフロントチャンバおよびガス流入路は、互いに区画することなく一体となっていてもよい。フロントチャンバおよびガス流入路に境目を設けて区切ると、膨張展開後においてその境目がくびれとなり、乗員を受け止めた際に折れなどが生じて衝撃吸収力等が低下するおそれがある。そこで上記構成では、フロントチャンバおよびガス流入路を全体で1つのチャンバとして膨張展開するよう設定していて、これによって衝撃吸収性能、さらには車外放出防止性能を高めている。 The above-described front chamber and gas inflow path may be integrated without being partitioned from each other. If the front chamber and the gas inflow passage are provided with a boundary, the boundary becomes constricted after inflating and deploying, and there is a possibility that the impact absorbing power or the like may be reduced due to a break when the occupant is received. Therefore, in the above configuration, the front chamber and the gas inflow path are set to inflate and deploy as a single chamber as a whole, thereby improving the shock absorption performance and further the outside release prevention performance.
 上記フロントチャンバは、オーバラップ部から当該カーテンエアバッグの上部へ向かってガスが流入するよう形成されるとよい。このようにして、ドアトリムに支えられているオーバラップ部から膨張展開を開始することで、フロントチャンバの衝撃吸収性能等を向上させることができる。また、通常のカーテンエアバッグは、その上部が締結部材等によって車両に固定されている。この上部は車両に固定されていることで揺動が起こりにくいため、上記フロントチャンバでは上部へ向かってガスを流入させることで揺動を抑えている。 The front chamber may be formed so that gas flows from the overlap portion toward the top of the curtain airbag. In this manner, by starting expansion and deployment from the overlap portion supported by the door trim, it is possible to improve the impact absorption performance of the front chamber. Moreover, the upper part of the normal curtain airbag is fixed to the vehicle by a fastening member or the like. Since the upper part is fixed to the vehicle, it is difficult for the rocking to occur. Therefore, the front chamber suppresses the rocking by allowing the gas to flow upward.
 上記フロントチャンバは、車両放出防止性能評価試験における試験装置であるインパクタの複数の打点位置のうち車両最前の打点位置を保護する部分に設けられていてもよい。一般のカーテンエアバッグのうち車両最前の打点位置を覆う部分は、それよりも前方に他のチャンバが存在していないため、周囲にあまり支えられておらず、張力が低下しやすい。しかし上記構成のフロントチャンバであれば、高い衝撃吸収性能等をもって、車両最前の打点位置を好適に保護することが可能になる。 The front chamber may be provided in a portion that protects the spot position at the forefront of the vehicle among a plurality of spot positions of an impactor that is a test device in the vehicle discharge prevention performance evaluation test. The portion of the general curtain airbag that covers the hitting position at the forefront of the vehicle is not supported by the surroundings because there is no other chamber ahead of it, and the tension tends to decrease. However, with the front chamber having the above-described configuration, it is possible to suitably protect the spot position at the forefront of the vehicle with high impact absorption performance and the like.
 上記のオーバラップ部は、少なくとも複数の打点位置よりも下方に位置するよう設けられているとよい。この構成によって、オーバラップ部は、各打点位置からの加重を吸収し、フロントチャンバをより好適に支えることが可能になる。 It is preferable that the overlap portion is provided so as to be positioned below at least a plurality of hit points. With this configuration, the overlap portion absorbs a load from each hitting point position and can more favorably support the front chamber.
 当該カーテンエアバッグは、フロントチャンバの後方であって座席の側方に配置されて当該カーテンエアバッグの膨張展開の当初にガスが流入するメインチャンバと、当該カーテンエアバッグの所定領域の表裏の基布が接合または一体化されて形成されメインチャンバからガス流入路へ向かってガスを案内する第1シーム部と、をさらに有するとよい。 The curtain airbag is disposed behind the front chamber and on the side of the seat, and the main chamber into which gas flows in at the beginning of the inflation and deployment of the curtain airbag, and the front and back of the predetermined area of the curtain airbag. It is preferable to further include a first seam portion that is formed by bonding or integrating the cloth and guides the gas from the main chamber toward the gas inflow path.
 上記のメインチャンバによれば、正規着座位置の乗員を迅速に保護することが可能となる。また、上記の第1シーム部によって、メインチャンバからガス流入路を介してフロントチャンバへという流れで膨張展開が進行する。フロントチャンバは、姿勢を崩した乗員が接触する場合が多く、特に乗員が姿勢を崩しやすいロールオーバ時に効果が期待される部位である。ロールオーバは側面衝突等に続いて起こる現象であって、その発生には最初の衝撃の発生との間にわずかながらの時間差が生じる。したがって、上記のようにメインチャンバに続いてフロントチャンバが膨張展開するという構成であれば、最初の側面衝突時と、続いて起こるロールオーバ時の両方に対応して乗員を好適に保護することが可能になる。 According to the main chamber described above, it is possible to quickly protect an occupant in the normal seating position. Further, the first seam portion causes expansion and deployment to proceed in a flow from the main chamber to the front chamber via the gas inflow path. The front chamber often comes into contact with an occupant whose posture has been lost, and is particularly a part that is expected to be effective during a rollover in which the occupant easily loses its posture. Rollover is a phenomenon that occurs following a side collision and the like, and a slight time difference occurs between the occurrence of the rollover and the first impact. Therefore, if the front chamber is inflated and deployed following the main chamber as described above, it is possible to suitably protect the occupant corresponding to both the first side collision and the subsequent rollover. It becomes possible.
 上記のフロントチャンバはメインチャンバに遅れて膨張展開が完了するディレーチャンバであるとよい。この構成であれば、フロントチャンバは、最初の側面衝突等に続いて起こるロールオーバに好適に対応することが可能になる。 The above-mentioned front chamber may be a delay chamber that completes expansion and deployment behind the main chamber. With this configuration, the front chamber can suitably cope with a rollover that occurs following the first side collision or the like.
 上記のメインチャンバは、所定領域の表裏の基布が接合または一体化されて形成されメインチャンバの膨張展開後の厚みを抑える第2シーム部を有してもよい。メインチャンバを所定の厚みに抑えることで、過度に膨張して目的の位置から外れてしまうおそれを低減できる。また、ガス容量を削減することで、フロントチャンバへのガスの供給を早めることが可能になる。 The above-mentioned main chamber may have a second seam portion formed by joining or integrating the base fabrics on the front and back sides of a predetermined region to suppress the thickness of the main chamber after expansion and deployment. By suppressing the main chamber to a predetermined thickness, it is possible to reduce the possibility that the main chamber is excessively expanded and deviated from the target position. Further, by reducing the gas capacity, it becomes possible to speed up the gas supply to the front chamber.
 本発明によれば、このような課題に鑑み、簡潔な構成でさらなる車外放出防止性能の向上が可能なカーテンエアバッグを提供することが可能となる。 According to the present invention, in view of such a problem, it is possible to provide a curtain airbag capable of further improving the out-of-vehicle emission prevention performance with a simple configuration.
本発明の第1実施形態にかかるカーテンエアバッグを例示する図である。It is a figure which illustrates the curtain airbag concerning 1st Embodiment of this invention. 図1のカーテンエアバッグを車両に取り付けた状態で例示する図である。It is a figure which illustrates the state which attached the curtain airbag of FIG. 1 to the vehicle. 図2のA-A断面図である。FIG. 3 is a cross-sectional view taken along line AA in FIG. 2. 図2のB-B断面図である。FIG. 3 is a sectional view taken along line BB in FIG. 本発明の第2実施形態にかかるカーテンエアバッグを例示する図である。It is a figure which illustrates the curtain airbag concerning 2nd Embodiment of this invention.
D1   …流出口の径、D2   …流入口の径、100・200  …エアバッグ、102  …インフレータ、104  …タブ、106  …ルーフサイドレール、108  …車両、109  …ドア、110  …サイドウィンドウ、112  …第1シーム部、114・202  …メインチャンバ、116  …前部座席、118  …経路、120・206  …ガス流入路、120a・206a  …流入口、122  …フロントチャンバ、122a  …オーバラップ部、124  …センタピラー、126  …ドアトリム、204  …第2シーム部、206b  …流出口 D1: Outlet diameter, D2: Inlet diameter, 100/200: Air bag, 102 ... Inflator, 104 ... Tab, 106 ... Roof side rail, 108 ... Vehicle, 109 ... Door, 110 ... Side window, 112 ... 1st seam portion, 114 · 202 ... main chamber, 116 ... front seat, 118 ... path, 120 · 206 ... gas inflow passage, 120a · 206a ... inlet, 122 ... front chamber, 122a ... overlap portion, 124 ... Center pillar, 126 ... Door trim, 204 ... Second seam, 206b ... Outlet
 以下に添付図面を参照しながら、本発明の好適な実施形態について詳細に説明する。かかる実施形態に示す寸法、材料、その他具体的な数値などは、発明の理解を容易とするための例示に過ぎず、特に断る場合を除き、本発明を限定するものではない。なお、本明細書及び図面において、実質的に同一の機能、構成を有する要素については、同一の符号を付することにより重複説明を省略し、また本発明に直接関係のない要素は図示を省略する。 Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The dimensions, materials, and other specific numerical values shown in the embodiments are merely examples for facilitating understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are denoted by the same reference numerals, and redundant description is omitted, and elements not directly related to the present invention are not illustrated. To do.
(第1実施形態)
 図1は、本発明の第1実施形態にかかるカーテンエアバッグを例示する図である。図1では膨張展開した状態のカーテンエアバッグ(以下、エアバッグ100と記載する)を例示している。なお、以下では図1に例示している車室内の右側面用のエアバッグ100を参照して説明を行うが、左側面用のエアバッグも同様の対称な構造を有する。
(First embodiment)
FIG. 1 is a diagram illustrating a curtain airbag according to the first embodiment of the present invention. FIG. 1 illustrates a curtain airbag (hereinafter referred to as an airbag 100) in an inflated and deployed state. In the following, description will be made with reference to the airbag 100 for the right side surface of the vehicle interior illustrated in FIG. 1, but the airbag for the left side surface has a similar symmetrical structure.
 エアバッグ100は、例えば表裏の面を構成する計2枚の基布から縫製する方法や、OPW(One-Piece Woven)を用いて紡織する方法などによって袋状に形成されている。エアバッグ100はガス発生装置であるインフレータ102を備えていて、エアバッグ100はインフレータ102から供給されるガスの圧力によって膨張して乗員を拘束する。 The airbag 100 is formed in a bag shape by, for example, a method of sewing from a total of two base fabrics constituting the front and back surfaces, a method of spinning using OPW (One-Piece Woven), or the like. The airbag 100 includes an inflator 102 that is a gas generator, and the airbag 100 is inflated by the pressure of gas supplied from the inflator 102 to restrain an occupant.
 エアバッグ100の上縁には車両108(図2参照)への取付け用の部位として、複数のタブ104が設けられている。タブ104は帯状に形成されていて、タブ104はボルトを使用するなどして車両108に固定される。 A plurality of tabs 104 are provided on the upper edge of the airbag 100 as parts for attachment to the vehicle 108 (see FIG. 2). The tab 104 is formed in a band shape, and the tab 104 is fixed to the vehicle 108 by using a bolt or the like.
 図2は、図1のカーテンエアバッグを車両108に取り付けた状態で例示する図である。通常、エアバッグ100は、巻回された状態または折り畳まれた状態で、車室内の側面部上方のルーフサイドレール106に取り付けられる。その際、エアバッグ100はルーフトリムの内側に収納されるため、車室内からは視認不能である。 FIG. 2 is a diagram illustrating the curtain airbag shown in FIG. 1 attached to the vehicle 108. Usually, the airbag 100 is attached to the roof side rail 106 above the side surface in the vehicle compartment in a wound state or a folded state. At that time, since the airbag 100 is housed inside the roof trim, the airbag 100 is not visible from the passenger compartment.
 車両108に側面衝突時等が発生すると、まず車両108に備えられたセンサ(図示省略)がその衝撃を検知し、これに起因してインフレータ102へ発火信号が発信される。すると、インフレータ102の火薬が燃焼し、発生したガスがエアバッグ100の内部へ供給される。このガスによって、エアバッグ100はサイドウィンドウ110等に沿って下方へ膨張展開して乗員の保護を行う。 When a side collision or the like occurs in the vehicle 108, a sensor (not shown) provided in the vehicle 108 first detects the impact, and an ignition signal is transmitted to the inflator 102 due to this. Then, the explosive in the inflator 102 burns and the generated gas is supplied into the airbag 100. With this gas, the airbag 100 is inflated and deployed downward along the side window 110 and the like to protect the occupant.
 エアバッグ100の膨張領域は、座席の位置などを考慮して複数の小部屋(チャンバ)に区画されている。以下、図1と図2とを参照しながら、当該エアバッグ100に設けられている各チャンバについて詳しく説明する。 The inflatable region of the airbag 100 is partitioned into a plurality of small rooms (chambers) in consideration of the seat position and the like. Hereinafter, the respective chambers provided in the airbag 100 will be described in detail with reference to FIGS. 1 and 2.
 図2に例示するように、インフレータ102よりも車両前方の領域へは、第1シーム部112によってガスが導かれる。第1シーム部112は、エアバッグ100の所定領域の表裏の基布を接合または一体化させた部位である。エアバッグ100は、インフレータ102が車両前後方向の中央付近に設けられたいわゆるセンターフィルタイプであって、第1シーム部112はインフレータ102の下方からガスを車両前方へ導けるように形成されている。 As illustrated in FIG. 2, the gas is guided by the first seam portion 112 to a region in front of the vehicle from the inflator 102. The first seam portion 112 is a portion where base fabrics on the front and back sides of a predetermined region of the airbag 100 are joined or integrated. The airbag 100 is a so-called center fill type in which the inflator 102 is provided near the center in the vehicle front-rear direction, and the first seam portion 112 is formed so as to guide gas from below the inflator 102 to the front of the vehicle.
 上記の第1シーム部112によって、車両前方側ではまずメインチャンバ114が膨張展開する。メインチャンバ114は、前部座席(図示省略)の側方に配置されていて、この前部座席における正規着座位置の乗員の主に頭部を保護する。 First main seam 114 is inflated and deployed by the first seam portion 112 on the front side of the vehicle. The main chamber 114 is disposed on the side of a front seat (not shown), and mainly protects the head of an occupant at a normal seating position in the front seat.
 ここで、図2には記号A1~A4、B1~B4およびC1で示される9個の打点を例示している。これらの打点は、FMVSS226(米国連邦自動車安全基準)セクション5.2:衝撃標的位置の決定(Determination of impact target locations)によって定められた車外放出防止性能評価試験における、試験装置であるインパクタ(図示省略)の衝突の打点位置である。FMVSS226ではこれらの打点にA1~A4、B1~B4およびC1などの名称はついていないが、これら各打点位置は、フロントサイドウィンドウおよびリアサイドウィンドウ(2列目以降すべてのサイドウィンドウ)のそれぞれにおける一次目標位置(Primary target)と二次目標位置(Secondary target)で定められるターゲットの位置、およびそれらを再構成して得られるターゲットの位置に一致している。本実施形態におけるこれら各打点位置は、ドア109の開口領域すなわちサイドウィンドウ110などの範囲を基準にして設定される。そして、エアバッグ100の車外放出防止性能評価試験では、エアバッグ100上の各打点にインパクタを衝突させ、エアバッグ100の車外放出量を測定する。メインチャンバ114は、これら複数の打点のうち主にA2~A4打点を保護している。 Here, FIG. 2 illustrates nine dots indicated by symbols A1 to A4, B1 to B4, and C1. These impact points are impactors (not shown) that are test equipment in the external vehicle emission prevention performance evaluation test defined by FMVSS 226 (Federal Automobile Safety Standards) Section 5.2: Determination impact target locations. ) Is the hit position of the collision. FMVSS 226 does not have names such as A1 to A4, B1 to B4, and C1 for these hit points, but each hit point position is the primary target in the front side window and rear side window (all side windows in the second and subsequent rows). It matches the target position determined by the position (Primary (target) and the secondary target position (Secondary target), and the target position obtained by reconfiguring them. These hitting point positions in the present embodiment are set based on the opening area of the door 109, that is, the range of the side window 110 or the like. In the vehicle 100 release prevention performance evaluation test of the airbag 100, the impactor is caused to collide with each hit point on the airbag 100, and the release amount of the airbag 100 outside the vehicle is measured. The main chamber 114 mainly protects A2 to A4 hit points among the plurality of hit points.
 メインチャンバ114へ流入したガスは、第1シーム部112の下方に形成されている経路118を通ってガス流入路120へと案内される。ガス流入路120は、当該エアバッグ100の最前に区画されているフロントチャンバ122へとガスを導く通路である。 The gas flowing into the main chamber 114 is guided to the gas inflow path 120 through a path 118 formed below the first seam portion 112. The gas inflow passage 120 is a passage that guides gas to the front chamber 122 that is partitioned in front of the airbag 100.
 ここで、当該エアバッグ100では、特にフロントチャンバ122における車外放出防止性能を向上させた構成となっている。以下、その具体的な構成および作用を詳述する。 Here, the airbag 100 has a configuration in which the anti-release performance in the front chamber 122 is improved. The specific configuration and operation will be described in detail below.
 まず図2に例示するように、当該エアバッグ100ではフロントチャンバ122へガスを供給するガス流入路120が、センタピラー124およびドアトリム126に重なるよう配置されている。特にガス流入路120は、そのガスの入り口である流入口120aの位置がセンタピラー124上に重なるよう設定されている。 First, as illustrated in FIG. 2, in the airbag 100, the gas inflow passage 120 that supplies gas to the front chamber 122 is disposed so as to overlap the center pillar 124 and the door trim 126. In particular, the gas inflow path 120 is set so that the position of the inflow port 120 a that is the gas inlet overlaps the center pillar 124.
 図3は、図2のA-A断面図である。図3に例示するように、ガス流入路120は、センタピラー124上の流入口120aから膨張を開始し、さらにドアトリム126上に沿って膨張してガスをフロントチャンバ122へと導く。センタピラー124は、サイドウィンドウ110等を含む車室内の側面部のうち、最も車内側へ突出している部位である。そして、ドアトリム126もまたサイドウィンドウ110よりも車内側へ突出している部位である。すなわち、ガス流入路120は、より車内側に突出している領域に沿って、車両中央側からフロントチャンバ122へ向かって伸びている。 FIG. 3 is a cross-sectional view taken along the line AA in FIG. As illustrated in FIG. 3, the gas inflow path 120 starts to expand from the inlet 120 a on the center pillar 124, and further expands along the door trim 126 to guide the gas to the front chamber 122. The center pillar 124 is a portion that protrudes to the innermost side among the side portions of the vehicle interior including the side window 110 and the like. The door trim 126 also projects from the side window 110 to the inside of the vehicle. That is, the gas inflow path 120 extends from the vehicle center side toward the front chamber 122 along a region that protrudes further toward the inside of the vehicle.
 図2に例示するように、ガス流入路120は、フロントチャンバ122の下部であるオーバラップ部122aに接続している。このオーバラップ部122aは、ドアトリム126に重なって膨張する部位である。そして、フロントチャンバ122はオーバラップ部122aから膨張を開始し、車両前方の主にA1打点付近において乗員の保護を行う。 As illustrated in FIG. 2, the gas inflow path 120 is connected to an overlap portion 122 a that is a lower portion of the front chamber 122. The overlap portion 122 a is a portion that overlaps with the door trim 126 and expands. And the front chamber 122 starts expansion | swelling from the overlap part 122a, and protects a passenger | crew mainly in the vicinity of A1 hitting point ahead of a vehicle.
 図4は、図2のB-B断面図である。図4に例示するように、フロントチャンバ122は、ドアトリム126に重なったオーバラップ部122aから膨張することで、膨張展開の当初からより車内側、すなわち乗員の近くへ位置して乗員と早期に接触することが可能になっている。加えて、フロントチャンバ122は、車外側がドアトリム126に支えられているために乗員からの荷重を効率よく吸収してその車外放出量を抑えることも可能になっている。また、フロントチャンバ122は、例えばサイドウィンドウ110が開口状態となった場合や、側面衝突によってドア109が車内側へ向かって変形した場合であっても、車外へ飛び出してしまうおそれが低くなる。 FIG. 4 is a cross-sectional view taken along the line BB in FIG. As illustrated in FIG. 4, the front chamber 122 is inflated from an overlap portion 122 a that overlaps the door trim 126, so that the front chamber 122 is positioned closer to the inside of the vehicle, that is, closer to the occupant from the beginning of the inflated deployment, and thus comes into early contact with the occupant. It is possible to do. In addition, since the front side of the front chamber 122 is supported by the door trim 126, it is also possible to efficiently absorb the load from the occupant and suppress the amount of discharge outside the vehicle. Further, the front chamber 122 is less likely to jump out of the vehicle even when, for example, the side window 110 is open or when the door 109 is deformed toward the vehicle interior due to a side collision.
 また、フロントチャンバ122は、オーバラップ部122aから当該エアバッグ100の上部へ向かってガスが流入するよう形成されている。ここで、エアバッグ100の上部は、タブ104によってルーフサイドレール106に固定されていて、揺動が起こりにくくなっている。したがって、フロントチャンバ122は、エアバッグ100の上部へ向かうようガスが流入されることで、膨張展開時に起こり得る揺動が抑えられている。 The front chamber 122 is formed so that gas flows from the overlap portion 122a toward the upper portion of the airbag 100. Here, the upper portion of the airbag 100 is fixed to the roof side rail 106 by the tab 104, and is less likely to swing. Therefore, the front chamber 122 is restrained from swinging that may occur during inflation and deployment by flowing gas toward the upper portion of the airbag 100.
 再び、図2を参照する。本実施形態では、フロントチャンバ122およびガス流入路120は、互いに区画されることなく、全体として一体のチャンバとなっている。例えば、フロントチャンバ122とガス流入路120との境目にシーム(縫い目などの接合部)を設けて区切ると、膨張展開後においてそこにくびれが発生し、乗員を受け止めた際に折れなどが生じて衝撃吸収力等が低下するおそれがある。そこで本実施形態では、フロントチャンバ122およびガス流入路120が全体で1つのチャンバとして膨張展開するよう設定していて、これによって衝撃吸収性能、さらには車外放出防止性能を高めている。 Again, refer to FIG. In the present embodiment, the front chamber 122 and the gas inflow path 120 are integrated with each other without being partitioned from each other. For example, if a seam (joint portion such as a seam) is provided at the boundary between the front chamber 122 and the gas inflow passage 120 to be separated, a constriction occurs after inflation and deployment, and a fold occurs when the occupant is received. There is a possibility that the shock absorbing ability and the like are reduced. Therefore, in the present embodiment, the front chamber 122 and the gas inflow path 120 are set so as to expand and deploy as a single chamber as a whole, thereby improving the shock absorption performance and further the out-of-vehicle discharge prevention performance.
 また、ガス流入路120は、特に流入口120aが、当該エアバッグ100内のガスの経路のうち最も径が小さい、最狭部となっている。ここで、「ガスの経路」とは、主にシームで区切られている膨張領域のことであり、「径」とは一方のシーム上の一点からその近隣の他方のシームに到達するまでの距離のことである。径の測り方は、具体的には、一方のシーム上の所定の位置にコンパスの芯を置き、そこを中心として半径が徐々に大きくなるよう円を描いていき、他方のシームに初めて接触したときのその円の半径が、そのガスの経路における径である。当該エアバッグ100内のガスの経路では、流入口120a(最狭部)が最も小さい径となっていて、この構成によってガス流入路120からはガスが流出しにくくなっている。したがって、ガス流入路120およびフロントチャンバ122はガス圧を高く維持することが可能になり、衝撃吸収性能および車外放出防止性能が向上している。 Further, in the gas inflow path 120, in particular, the inflow port 120 a is the narrowest part having the smallest diameter among the gas paths in the airbag 100. Here, the “gas path” is an expansion region that is mainly divided by seams, and the “diameter” is the distance from one point on one seam to the other seam in the vicinity. That is. Specifically, the diameter is measured by placing a compass core at a predetermined position on one seam, drawing a circle with the radius gradually increasing around it, and contacting the other seam for the first time. The radius of the circle at that time is the diameter in the gas path. In the gas path in the airbag 100, the inlet 120a (narrowest portion) has the smallest diameter, and this configuration makes it difficult for the gas to flow out from the gas inflow path 120. Therefore, the gas inflow path 120 and the front chamber 122 can maintain a high gas pressure, and the shock absorption performance and the vehicle outside discharge prevention performance are improved.
 以上説明したように、当該エアバッグ100は、ガス流入路120からフロントチャンバ122にかけて、車外側がセンタピラー124およびドアトリム126によって支えられている部位に沿って膨張展開する構成となっている。そして、これらによって当該エアバッグ100は、簡潔な構成で高い衝撃吸収性能および車外放出防止性能を発揮可能となっている。 As described above, the airbag 100 is configured to inflate and deploy from the gas inflow path 120 to the front chamber 122 along the portion where the outside of the vehicle is supported by the center pillar 124 and the door trim 126. As a result, the airbag 100 can exhibit high impact absorption performance and out-of-vehicle discharge prevention performance with a simple configuration.
 当該エアバッグ100では、上記説明したフロントチャンバ122を利用して、図2に例示したA1打点の位置を保護している。このA1打点は、車両最前の打点位置である。通常、カーテンエアバッグ上におけるA1打点を保護する部分は、それよりも前方に他のチャンバが存在していないため、周囲にあまり支えられておらず、張力が低下しやすい。しかし当該エアバッグ100のフロントチャンバ122であれば、高い衝撃吸収性能等をもって、A1打点を好適に保護することが可能である。 In the airbag 100, the position of the A1 hit point illustrated in FIG. 2 is protected using the front chamber 122 described above. This A1 hit point is the hit point position in front of the vehicle. Usually, the portion that protects the A1 hitting point on the curtain airbag is not supported by the surroundings because there is no other chamber ahead of it, and the tension tends to decrease. However, with the front chamber 122 of the airbag 100, it is possible to suitably protect the A1 hit point with high impact absorption performance and the like.
 また、フロントチャンバ122のオーバラップ部122aは、少なくとも複数の打点位置よりも下方に位置するよう設けてある。具体的には、オーバラップ部122aは、下列に位置するA2打点よりも下方に位置している。この構成によって、オーバラップ部122aを利用して、各打点位置からの加重を吸収し、フロントチャンバ122およびメインチャンバ114等をより好適に支えることが可能になっている。 Further, the overlap portion 122a of the front chamber 122 is provided so as to be positioned below at least a plurality of hit points. Specifically, the overlap part 122a is located below the A2 hit point located in the lower row. With this configuration, it is possible to absorb the load from each hit point position using the overlap portion 122a and more favorably support the front chamber 122, the main chamber 114, and the like.
 また、図2に例示するように、当該エアバッグ100では、第1シーム部112やガス流入路120によるガスの流れによって、メインチャンバ114からフロントチャンバ122へという順序で膨張展開が進行する。このように、フロントチャンバ122はメインチャンバ114に遅れて膨張展開が完了するディレーチャンバとして設定されている。 Further, as illustrated in FIG. 2, in the airbag 100, inflation and deployment proceed in the order from the main chamber 114 to the front chamber 122 due to the gas flow through the first seam portion 112 and the gas inflow path 120. In this way, the front chamber 122 is set as a delay chamber that completes the expansion and deployment behind the main chamber 114.
 フロントチャンバ122は、姿勢を崩した乗員が接触する場合が多く、特にロールオーバ時に効果が期待される部位である。ロールオーバは側面衝突等に続いて起こる現象であって、その発生には最初の衝撃の検知からわずかながらの時間差が生じる。したがって、上記のようにメインチャンバ114に続いてフロントチャンバ122が膨張展開するという構成であれば、側面衝突時にはメインチャンバ114によって正規着座位置における乗員を迅速に保護し、続いて起こるロールオーバ時には姿勢を崩した乗員をフロントチャンバ122によって保護することができる。このように、当該エアバッグ100は、側面衝突時とロールオーバ時の両方に好適に対応することが可能となっている。 The front chamber 122 is often a part that is in contact with an occupant whose posture has been lost, and is particularly expected to be effective during a rollover. Rollover is a phenomenon that occurs after a side collision or the like, and its occurrence has a slight time difference from the detection of the first impact. Therefore, if the front chamber 122 is inflated and deployed following the main chamber 114 as described above, the main chamber 114 quickly protects the occupant at the normal seating position at the time of a side collision, and the posture at the subsequent rollover. A passenger who breaks down can be protected by the front chamber 122. Thus, the airbag 100 can appropriately cope with both the side collision and the rollover.
(第2実施形態)
 図4は、本発明の第2実施形態にかかるカーテンエアバッグを例示する図である。当該カーテンエアバッグ(以下、エアバッグ200と記載する)は、シーム部等の構成の点で、第1実施形態のエアバッグ100と異なっている。
(Second Embodiment)
FIG. 4 is a diagram illustrating a curtain airbag according to the second embodiment of the present invention. The curtain airbag (hereinafter referred to as an airbag 200) is different from the airbag 100 of the first embodiment in terms of the configuration of a seam portion and the like.
 本実施形態のエアバッグ200では、メインチャンバ202に第2シーム部204が備えられている。第2シーム部204は、メインチャンバ202の所定領域の表裏の基布が接合または一体化した構成となっていて、メインチャンバ202の膨張展開後の厚みを抑えることが可能になっている。このようにメインチャンバ202を所定の厚みに抑えることで、メインチャンバ202は過度に膨張して目的の位置から外れてしまうおそれが低減されている。また第2シーム部204を設けることで、例えばメインチャンバ202のガス容量を削減してフロントチャンバ122へのガスの供給を早めるなど、エアバッグ200の膨張展開の進行具合も任意に設定することが可能になる。 In the airbag 200 of the present embodiment, the second seam portion 204 is provided in the main chamber 202. The second seam portion 204 has a structure in which base fabrics on the front and back sides of a predetermined region of the main chamber 202 are joined or integrated, and the thickness of the main chamber 202 after expansion and deployment can be suppressed. By suppressing the main chamber 202 to a predetermined thickness in this way, the possibility that the main chamber 202 will be excessively expanded and deviated from the target position is reduced. Further, by providing the second seam portion 204, for example, the progress of the inflation and deployment of the airbag 200 can be arbitrarily set, for example, the gas capacity of the main chamber 202 is reduced and the gas supply to the front chamber 122 is accelerated. It becomes possible.
 当該エアバッグ200の、ガス流入路206における流出口206bの径D1は、流入口206aの径D2よりも小径に設定されている(D1<D2)。また、この流出口206bは、当該エアバッグ200のすべてのガスの経路のうちで最も狭い最狭部であって、すべてのガスの経路のうち最も径の小さい部分となっている。これにより、フロントチャンバ122は、ガスの流出量が抑えられ、内圧を高く維持することが可能になっている。またこの構成によって、フロントチャンバ122への単位時間あたりのガスの供給量が制限され、フロントチャンバ122の膨張完了時点をロールオーバの発生時に合わせて遅らせることができる。このように、ガス流入路206は、流入口206aと流出口との大小関係を任意に設定することで、フロントチャンバ122の膨張完了時点も任意に設定することが可能である。 The diameter D1 of the outlet 206b in the gas inflow path 206 of the airbag 200 is set to be smaller than the diameter D2 of the inlet 206a (D1 <D2). The outflow port 206b is the narrowest narrowest portion of all the gas paths of the airbag 200 and is the smallest diameter portion of all the gas paths. As a result, the front chamber 122 can suppress the outflow amount of gas and can maintain the internal pressure high. Also, with this configuration, the amount of gas supplied to the front chamber 122 per unit time is limited, and the expansion completion time of the front chamber 122 can be delayed in accordance with the occurrence of rollover. As described above, the gas inflow path 206 can arbitrarily set the expansion completion time of the front chamber 122 by arbitrarily setting the magnitude relationship between the inflow port 206a and the outflow port.
 以上、添付図面を参照しながら本発明の好適な実施形態について説明したが、以上に述べた実施形態は、本発明の好ましい例であって、これ以外の実施態様も、各種の方法で実施または遂行できる。特に本願明細書中に限定される主旨の記載がない限り、この発明は、添付図面に示した詳細な部品の形状、大きさ、および構成配置等に制約されるものではない。また、本願明細書の中に用いられた表現および用語は、説明を目的としたもので、特に限定される主旨の記載がない限り、それに限定されるものではない。 The preferred embodiments of the present invention have been described above with reference to the accompanying drawings. However, the embodiments described above are preferred examples of the present invention, and other embodiments can be implemented or performed by various methods. Can be carried out. The invention is not limited to the detailed shape, size, configuration, and the like of the components shown in the accompanying drawings unless otherwise specified in the present specification. In addition, expressions and terms used in the present specification are for the purpose of explanation, and are not limited thereto unless otherwise specified.
 したがって、当業者であれば、特許請求の範囲に記載された範疇内において、各種の変更例または修正例に想到し得ることは明らかであり、それらについても当然に本発明の技術的範囲に属するものと了解される。 Therefore, it is obvious for those skilled in the art that various changes and modifications can be conceived within the scope of the claims, and these naturally belong to the technical scope of the present invention. It is understood.
 また、上記実施形態においては本発明にかかるカーテンエアバッグを自動車に適用した例を説明したが、自動車以外にも航空機や船舶などに適用することも可能であり、同様の作用効果を得ることができる。 Moreover, in the said embodiment, although the example which applied the curtain airbag concerning this invention to the motor vehicle was demonstrated, it is also possible to apply to an aircraft, a ship, etc. besides a motor vehicle, and can obtain the same effect. it can.
 本発明は、車両の側面衝突時やロールオーバ(横転)時に、乗員保護を目的として車室内の側面部に沿って膨張展開するカーテンエアバッグに利用することができる。 The present invention can be used for a curtain airbag that inflates and deploys along a side surface of a vehicle interior for the purpose of protecting an occupant during a vehicle side collision or rollover (rollover).

Claims (10)

  1.  車室内の側面部上方に収納され、該側面部に沿って膨張展開するカーテンエアバッグにおいて、
     ガスが流入して膨張するチャンバのうち車両前後方向の最前に区画されるフロントチャンバであって、ドアトリムに重なって膨張するオーバラップ部を有するフロントチャンバと、
     車両前後方向の中央側から前記オーバラップ部へ向かって前記ドアトリムに重なって伸びるガス流入路であって、少なくとも一部がセンタピラーに重なって配置されているガス流入路と、を備えることを特徴とするカーテンエアバッグ。
    In the curtain airbag that is stored above the side surface of the vehicle interior and inflates and deploys along the side surface,
    A front chamber that is partitioned in the fore-and-aft direction of the vehicle in a chamber in which gas flows in and expands, and has an overlap portion that expands by overlapping with a door trim; and
    A gas inflow passage extending over the door trim from the center side in the vehicle longitudinal direction toward the overlap portion, and at least a portion of the gas inflow passage is disposed over the center pillar. Curtain airbag.
  2.  前記ガス流入路の入り口は、前記センタピラーに重なっていることを特徴とする請求項1に記載のカーテンエアバッグ。 The curtain airbag according to claim 1, wherein an entrance of the gas inflow passage overlaps the center pillar.
  3.  前記ガス流入路は、所定の位置に、当該カーテンエアバッグ内のガスの経路のうち最も径が小さい最狭部を有することを特徴とする請求項1または2に記載のカーテンエアバッグ。 3. The curtain airbag according to claim 1 or 2, wherein the gas inflow path has a narrowest portion having a smallest diameter among gas paths in the curtain airbag at a predetermined position.
  4.  前記フロントチャンバおよびガス流入路は、互いに区画することなく一体となっていることを特徴とする請求項1から3のいずれか1項に記載のカーテンエアバッグ。 The curtain airbag according to any one of claims 1 to 3, wherein the front chamber and the gas inflow passage are integrated without being partitioned from each other.
  5.  前記フロントチャンバは、前記オーバラップ部から当該カーテンエアバッグの上部へ向かってガスが流入するよう形成されることを特徴とする請求項1から4のいずれか1項に記載のカーテンエアバッグ。 The curtain airbag according to any one of claims 1 to 4, wherein the front chamber is formed such that gas flows from the overlap portion toward an upper portion of the curtain airbag.
  6.  前記フロントチャンバは、車両放出防止性能評価試験における試験装置であるインパクタの複数の打点位置のうち車両最前の打点位置を保護する部分に設けられていることを特徴とする請求項1から5のいずれか1項に記載のカーテンエアバッグ。 The said front chamber is provided in the part which protects the front spot position of a vehicle among the plurality of spot positions of the impactor which is a test device in a vehicle discharge prevention performance evaluation test. A curtain airbag according to claim 1.
  7.  前記オーバラップ部は、少なくとも前記複数の打点位置よりも下方に位置するよう設けられていることを特徴とする請求項6に記載のカーテンエアバッグ。 The curtain airbag according to claim 6, wherein the overlap portion is provided at least below the plurality of hitting point positions.
  8.  前記フロントチャンバの後方であって座席の側方に配置されて当該カーテンエアバッグの膨張展開の当初にガスが流入するメインチャンバと、
     当該カーテンエアバッグの所定領域の表裏の基布が接合または一体化されて形成され前記メインチャンバから前記ガス流入路へ向かってガスを案内する第1シーム部と、をさらに有することを特徴とする請求項1から7のいずれか1項に記載のカーテンエアバッグ。
    A main chamber which is arranged behind the front chamber and on the side of the seat and into which gas flows in at the beginning of the inflation and deployment of the curtain airbag;
    And a first seam portion that is formed by joining or integrating base fabrics in a predetermined region of the curtain airbag to guide gas from the main chamber toward the gas inflow path. The curtain airbag according to any one of claims 1 to 7.
  9.  前記フロントチャンバはメインチャンバに遅れて膨張展開が完了するディレーチャンバであることを特徴とする請求項8に記載のカーテンエアバッグ。 9. The curtain airbag according to claim 8, wherein the front chamber is a delay chamber that completes inflating and deploying behind the main chamber.
  10.  前記メインチャンバは、所定領域の表裏の基布が接合または一体化されて形成され該メインチャンバの膨張展開後の厚みを抑える第2シーム部を有することを特徴とする請求項8または9に記載のカーテンエアバッグ。 The said main chamber is formed by joining or integrating the base fabric of the front and back of a predetermined area | region, It has the 2nd seam part which suppresses the thickness after expansion | deployment expansion | deployment of this main chamber, It is characterized by the above-mentioned. Curtain airbag.
PCT/JP2012/069384 2011-08-01 2012-07-31 Curtain airbag WO2013018781A1 (en)

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US9211863B2 (en) 2014-01-28 2015-12-15 Toyoda Gosei Co., Ltd. Head-protecting airbag device

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JP6824655B2 (en) * 2016-07-27 2021-02-03 日本プラスト株式会社 Airbag

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JP2005096575A (en) * 2003-09-24 2005-04-14 Toyoda Gosei Co Ltd Head protective air bag
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JP2008056117A (en) * 2006-08-31 2008-03-13 Toyota Motor Corp Head protection airbag device
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US20150097360A1 (en) * 2012-04-23 2015-04-09 Honda Motor Co., Ltd. Curtain airbag device
US9308884B2 (en) * 2012-04-23 2016-04-12 Honda Motor Co., Ltd. Curtain airbag device
US9211863B2 (en) 2014-01-28 2015-12-15 Toyoda Gosei Co., Ltd. Head-protecting airbag device

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