The present application claims priority from Japanese Patent Application No. 2020-165664 of Yanagisawa et al., filed on Sep. 30, 2020, and Japanese Patent Application No. 2020-165665 of Yanagisawa et al., filed on Sep. 30, 2020, the entire disclosures of which are incorporated herein by reference.
The present disclosure relates to a wearable airbag device for protecting the hip of a wearer.
WO 2019/207474 A1 discloses a wearable airbag device for protecting the hip of a wearer such as an elderly person in the event of a fall or the like. This airbag device is designed to be wrapped around the waist of the wearer so as to inflate and deploy an airbag downward for protecting his hip when activated.
An airbag configured to be inflated with an inflation gas is usually inflated thick in such a manner that both outer surfaces thereof curve. Accordingly, when the airbag of the above reference is inflated and deployed downward from the state mounted around the waist, there may be a fear that the airbag as inflated floats away from the hip and fails to cover the hip quickly and adequately in the event of a fall or the like.
An exemplary embodiment in the present disclosure relates to a wearable airbag device adapted to be worn by a wearer for protecting the hip of the wearer, the airbag device including an airbag that is adapted to be put on a circumference of the pelvis of the wearer and configured to be inflated with an inflation gas. The airbag includes: an inner wall that is configured to face the wearer at airbag deployment, the inner wall having a circumferential edge; an outer wall that is configured to face away from the wearer at airbag deployment, the outer wall having a circumferential edge jointed with the circumferential edge of the inner wall so that the airbag has a substantially board shape when inflated; a contact portion that is disposed in an upper reach of a stream of the inflation gas and is configured to be deployed at least at a side of the pelvis at airbag deployment; at least one protecting portion that is configured to be deployed in such a manner as to extend downward from the contact portion for covering an outer side of the trochanter of femur of the wearer at airbag deployment; and a float-preventing means that is configured to prevent the protecting portion from floating away from the body of the wearer at airbag deployment.
Another exemplary embodiment in the present disclosure relates to a wearable airbag device adapted to be worn by a wearer for protecting the hip of the wearer, the airbag device including a gas generator; and an airbag that is adapted to be put on a circumference of the pelvis of the wearer and configured to be inflated with an inflation gas fed from the gas generator. The airbag includes: an inner wall that is configured to face the wearer at airbag deployment, the inner wall having a circumferential edge; an outer wall that is configured to face away from the wearer at airbag deployment, the outer wall having a circumferential edge jointed with the circumferential edge of the inner wall so that the airbag has a substantially board shape when inflated; an applying portion that is disposed in a vicinity of an upper end of the airbag and adapted to be applied to the circumference of the pelvis; two protecting portions each of which is configured to cover an outer side of the trochanter of femur of the wearer; a gas-feeding path that is connected with the gas generator and adapted to be disposed at the back of the pelvis; and two gas channels each of which provides gas communication between the gas-feeding path and each of the protecting portions, each of the gas channels extending downwardly and outwardly in a left and right direction from the gas-feeding path, then turning upward at a position beneath the protecting portion and communicating with the protecting portion by a leading end thereof.
Yet another exemplary embodiment in the present disclosure relates to a wearable airbag device adapted to be worn by a wearer for protecting the hip of the wearer, the airbag device including an airbag that is adapted to be put on a circumference of the pelvis of the wearer and configured to be inflated with an inflation gas. The airbag includes: an inner wall that is configured to face the wearer at airbag deployment, the inner wall having a circumferential edge; an outer wall that is configured to face away from the wearer at airbag deployment, the outer wall having a circumferential edge jointed with the circumferential edge of the inner wall so that the airbag has a substantially board shape when inflated; a contact portion that is disposed in a vicinity of an upper end of the airbag as deployed and configured to be deployed at least at a side of the pelvis; and at least one protecting portion that is configured to be deployed in such a manner as to extend downward from the contact portion for covering an outer side of the trochanter of femur of the wearer at airbag deployment. The airbag has a folded form that has a reduced width in an up and down direction compared to that of the airbag in an unfolded state in which the inner wall and outer wall are laid flat one over another. The folded form of the airbag is so configured as to allow the contact portion to be inflated prior to the protecting portion, and push and deploy the protecting portion downward in an initial stage of airbag deployment.
Exemplary embodiments of the present disclosure are described below with reference to the accompanying drawings. However, the invention is not limited to the embodiments disclosed herein. All modifications within the appended claims and equivalents relative thereto are intended to be encompassed in the scope of the claims.
A wearable airbag device S1 in accordance with the first exemplary embodiment is configured to be wrapped around the hip MW (more particularly, around the pelvis MP) of a wearer M, as can be seen in
As can be seen in
The operation control device 1 includes a sensor part 2 that includes an angular velocity sensor capable of sensing angular velocities around three axes in up and down, front and rear, and left and right directions, and an acceleration sensor capable of sensing accelerations in the three-axis directions. The operation control device 1 is configured to actuate the gas generator 5 in response to a signal fed from the sensor part 2 as has sensed a falling behavior different from a normal behavior of the wearer M. More particularly, the operation control device 1 includes a determining means that is configured to determine based on various thresholds, and is configured to actuate the gas generator 5 upon sensing a fall of the wearer M based on the determination by the determining means. The operation control device 1 further includes a power source composed of a not-shown battery or the like for operation of the sensor part 2 and for emission of an actuating signal to the gas generator 5.
The airbag 10 is made of a sheet material having flexibility. The airbag 10 of this specific embodiment is made of a fabric woven with polyester yarns, polyimide yarns or the like. The airbag 10 is adapted to be wrapped around the pelvis MP of the wearer M through the use of a later-described belt 27 of the outer cover 25. In this embodiment, the airbag 10 is configured to be disposed on left and right sides of the hip MW of the wearer M when worn, as can be seen in
The gas-feeding path 12 is designed to be inflated into a rod shape elongated substantially along a left and right direction. The gas-feeding path 12 of this embodiment is adapted to be deployed at the rear of the pelvis MP of the wearer M though not depicted in detail. In this embodiment, the gas generator 5 is connected to the gas-feeding path 12 for feeding the airbag 10 with an inflation gas (
Referring to
The contact portion 15 of this embodiment is a portion continuous with the gas-feeding path 12 and disposed on extensions to the left and right of the gas-feeding path 12 in the airbag 10 as laid flat. The contact portion 15 is disposed in an upper end 13a portion of the bag body 13. i.e. in an upper reach of a stream of the inflation gas G.
The contact portion 15 is a portion applied to the circumference of the hip MW of the wearer M with the use of a later-described belt 27 of the outer cover 25. The contact portion 15 is designed to be deployed on a side of the pelvis MP of the wearer M at airbag deployment, as can be seen in
The protecting portion 16 is designed to extend downward from the contact portion 15, and disposed in a lower end 13b portion of the bag body 13. The protecting portion 16 is designed to cover an outer side of the trochanter TP of femur as the object of protection at airbag deployment. In this embodiment, in order to cover the trochanter TP of femur amply, the protecting portion 16 as laid flat has a substantially trapezoidal outer shape that has a greater width in the left and right direction than that in the up and down direction, and slightly narrows toward the lower end 16a. The width in the left and right direction of the protecting portion 16 is substantially identical to that of the contact portion 15. As can be seen in
In each of the bag bodies 13 (13L, 13R) of the airbag 10, the contact portion 15 and the protecting portion 16 are partitioned by a tether 18. In this embodiment, the tether 18 is arranged in such a manner as to block substantially an entirety of a passage between the contact portion 15 and protecting portion 16. The tether 18 is designed to regulate a clearance between the inner wall 10a and the outer wall 10b at airbag deployment. The tether 18 is formed into a band whose length is slightly shorter than a width in the left and right direction of the bag body 13. An inner edge 18a of the tether 18 is jointed to the inner wall 10a by an inner joint 22 and an outer edge 18b, which is opposite from the inner edge 18a, is jointed to the outer wall 10b by an outer joint 23, as can be seen in
The outer cover 25 is made of a flexible fabric having better touch than the base cloth of the airbag 10. The outer cover 25 covers an entirety of the outer circumference of the airbag 10. The outer cover 25 includes an inner wall 25a that is disposed towards the wearer M (i.e. in the inner side) when worn, and an outer wall 25b that is disposed on the outer side when worn, and is formed by jointing (or sewing) circumferential edges of the inner wall 25a and outer wall 25b together. An outer shape of the outer cover 25 as laid flat is greater than the airbag 10 as laid flat so as to allow the airbag 10 to inflate smoothly inside the outer cover 25, as can be seen in
The wearable airbag device S1 in accordance with the first exemplary embodiment is put on around the hip MW (pelvis MP) of the wearer M in a wrapping manner by fastening the leading ends 27a of the belts 27 together with the use of the hook-and-loop fastener 28 (as the fastening means). If the sensor part 2 detects a falling behavior of the wearer M as wearing the airbag device S1, the operation control device 1 sends an actuating signal to the gas generator 5, the gas generator 5 feeds an inflation gas to the airbag 10, so that the airbag 10 is deployed as shown in
In the wearable airbag device S1 in accordance with the first exemplary embodiment, although each of the protecting portions 16 for covering an outer side of the trochanter TP of femur (i.e. the object of protection) is configured to be deployed in such a manner as to extend downward from the contact portion 15 disposed at a side of the pelvis MP, the tether 18 serving as the float-preventing means will prevent the protecting portion 16 from floating away from the hip MW, in other words, help deploy the protecting portion 16 in proximity to the object of protection (i.e. the trochanter TP of femur), as can be seen in
Therefore, the wearable airbag device S1 in accordance with the first exemplary embodiment is able to protect the hip MW of the wearer M in a steady fashion.
In the wearable airbag device S1 in accordance with the first exemplary embodiment, the airbag 10 (more particularly, the bag body 13) includes, as the float-preventing means, the tether 18 that connects the inner wall 10a and the outer wall 10b at a vicinity of the border between the contact portion 15 and the protecting portion 16 inside the bag body 13. The tether 18 will suppress the airbag 10 or bag body 13 from being inflated too thick. Further, the tether 18 is arranged such that the inner joint 22 that connects the inner edge 18a of the tether 18 to the inner wall 10a is disposed at a higher position than the outer joint 23 that connects the outer edge 18b of the tether 18 to the outer wall 10b. In other words, the tether 18 makes the substantial film length L1 of the inner wall 15a of the contact portion 15 shorter than the substantial film length L2 of the outer wall 15b of the contact portion 15. This configuration will help bend the airbag 10 (or bag body 13) at the inner joint 22 at airbag deployment so that the lower end 16a the protecting portion 16 is directed inward, i.e. toward the wearer M, as can be seen in
The airbag may be configured like an airbag 10A depicted in
With the airbag 10A (or bag body 13A) configured as described above, the tuck 35 makes a film length in the up and down direction of the inner wall 10a shorter than that of the outer wall 10b, thus will help bend the inner wall 10a at the tuck 35 (
The airbag may be configured like an airbag 10B depicted in
When the airbag 10B (or bag body 13B) configured as described above is deployed, the contact portion 15B will be inflated with an inflation gas first, then the protecting portion 16B will be inflated. The protecting portion 16B will receive an inflation gas G from the contact portion 15B via the communication holes 41 formed in the bulkhead 40 as can be seen in
An airbag 50 for use in a wearable airbag device S2 in accordance with the second exemplary embodiment is now described in reference to
The gas-feeding path 51 is disposed in a vicinity of the upper end 50c of and at the center in a left and right direction of the airbag 50. The gas-feeding path 51 is configured to be inflated into a rod shape elongated substantially along the left and right direction at the back of the pelvis MP of the wearer M, as can be seen in
Each of the protecting portions 52 (52L, 52R) is disposed such that the upper end is disposed at a farther downward position than the upper edge of the gas-feeding path 51, in a stepped manner with respect to the gas-feeding path 51, as can be seen in
In the wearable airbag device S2 in accordance with the second exemplary embodiment employing the airbag 50, each of the protecting portions 52 for covering outer sides of the trochanters TP of femurs is designed to receive an inflation gas for inflation from the lower side via the gas-feeding path 51 and gas channel 53, in an initial stage of airbag deployment. With this configuration, referring to
The wearable airbag devices of the foregoing embodiments include a belt so as to be put on around the hip with the use of the belt. However, the application of the invention should not be limited to the disclosed embodiments. By way of example, the invention may be applied to a wearable airbag device which is formed into a vest, a jacket or the like for wearing on the torso and configured to deploy an airbag from the lower end as worn. Although the airbags of the foregoing embodiments are each stored inside the outer cover in an unfolded state, the airbag may be stored inside the outer cover in a folded state.
A wearable airbag device S3 in accordance with the third exemplary embodiment is now described. As can be seen in
Referring to
The airbag 110 is made of a sheet material having flexibility. The airbag 110 of this specific embodiment is made of a fabric woven with polyester yarns, polyimide yarns or the like. As can be seen in
The gas-feeding path 112 is designed to be inflated into a rod shape elongated substantially along a left and right direction. The gas-feeding path 112 of this embodiment is adapted to be deployed at the back of the pelvis MP of the wearer M though not depicted in detail. In this embodiment, the gas generator 5 is connected to the gas-feeding path 112 for feeding the airbag 110 with an inflation gas, as shown in
Referring to
The contact portion 115 of this embodiment is a portion continuous with the gas-feeding path 112 and disposed on extensions to the left and right of the gas-feeding path 112 in the airbag 110 as laid flat. That is, the contact portion 115 is disposed in a vicinity of upper ends 113b of the bag bodies 113. The contact portion 115 is designed to be deployed on the left and right sides of the pelvis MP of the wearer M at airbag deployment in a worn state, as can be seen in
Each of the protecting portions 116 is designed to extend downward from the contact portion 115 and cover an outer side of the trochanter TP of femur as an object of protection at airbag deployment. In this embodiment, in order to cover the trochanter TP of femur amply, the protecting portion 116 as laid flat has a substantially trapezoidal outer shape that has a greater width in the left and right direction than that in the up and down direction, and slightly narrows toward the lower end. The width in the left and right direction of the protecting portion 116 is substantially identical to that of the contact portion 115. As can be seen in
The airbag 110 of this embodiment is stored in a storage in the form of a folded body 120, a form of the airbag 110 that has been folded and has a reduced width in an up and down direction compared to that in an unfolded state in which the inner wall 110a and the outer wall 110b are laid flat one over another. In this embodiment, the folded body 120 is stored inside the outer cover 125, and put on around the pelvis MP of the wearer M in that state, as can be seen in
The outer cover 125 covering the outer circumference of the folded body 120 is formed substantially into a band shape. The outer cover 125 of this embodiment is made of a flexible fabric having better touch than the base cloth of the airbag 110. The outer cover 125 includes an inner wall 126 that is disposed in the inner side (i.e. towards the wearer M) when worn, and an outer wall 129 that is disposed on the outer side when worn. In this embodiment, a lower edge portion 126a of the inner wall 126 and a lower edge portion 129a of the outer wall 129 are jointed together in such a manner as to be separable from one another when pushed by the airbag 110 in an initial stage of airbag deployment. More particularly, the lower edge portion 126a of the inner wall 126 and the lower edge portion 129a of the outer wall 129 are jointed together by a hook-and-loop fastener 132 including hooks 132a and loops 132b. The hook-and-loop fastener 132 serves as a jointing means. A joint strength of the lower edge portion 126a and the lower edge portion 129a is such that they are unjointed when pushed by the inflated airbag 110 in the initial stage of airbag deployment. Each of the inner wall 126 and outer wall 129 includes, in the lower edge portion 126a/29a, a folded-in portion 127/130 that is folded inward. The hook-and-loop fastener 132 is disposed in root portions 127a and 130a of the folded-in portions 127 and 130 to join the root portions 127a and 130a. When the hooks 132a and loops 132b of the hook-and-loop faster 132 are disengaged from one another in the initial stage of airbag deployment, the folded-in portions 127 and 130 unfold and extend downward. The folded-in portions 127 and 130 as unfolded and extended downward serve as a guide portion that leads the airbag 110 to deploy downward. As can be seen in
The outer cover 125 includes a fastening means for application to the hip MW of the wearer M at opposite ends 125a, 125b in the length direction. The fastening means in this embodiment is composed of a hook-and-loop fastener 134 including hooks 134a and loops 134b engageable with one another so as to enable the wearer M to wear the airbag device S3 easily according to the size of the waist.
The wearable airbag device S3 in accordance with the third exemplary embodiment is put on around the hip MW (pelvis MP) of the wearer M in a wrapping manner by fastening the opposite ends 125a, 125b of the outer cover 125 together with the use of the hook-and-loop fastener 134 (as the fastening means). If the sensor part 2 detects a falling behavior of the wearer M as wearing the airbag device S3, the operation control device 1 sends an actuating signal to the gas generator 5, the gas generator 5 feeds an inflation gas to the airbag 110, so that the airbag 110 unfolds and deploys as shown in
In the wearable airbag device S3 in accordance with the third exemplary embodiment, although each of the protecting portions 116 for covering an outer side of the trochanter TP of femur (i.e. the object of protection) is configured to be deployed in such a manner as to extend downward from the contact portion 115 disposed at a side of the pelvis MP, the airbag 110 is configured so that the contact portions 115 are inflated first and the contact portions 115 as inflated push and deploy the protecting portions 116 downward, as can be seen in
Therefore, the wearable airbag device S3 in accordance with the third exemplary embodiment is able to protect the hip MW of the wearer M in a steady fashion.
More particularly, in the wearable airbag device S3 in accordance with the third exemplary embodiment, the contact portion 115 is folded in a concertina fashion while the protecting portion 116 is rolled from the lower edge 116a. This configuration will help inflate the contact portion 115 quickly so that the protecting portion 116 as has been folded will unfold and be deployed downward quickly. In this embodiment, especially, since the contact portion 115 is continuous with the gas-feeding path 112 connected with the gas generator 5 and configured to be inflated into a rod shape integrally with the gas-feeding path 112, the contact portion 115 will be inflated quickly. Further, since the protecting portion 116 is disposed immediately below the concertina-fold portion 120a (i.e. the contact portion 115) in a rolled state, the protecting portion 116 will be pushed downward by the contact portion 115 as inflated and be inflated while unfolding as can be seen in
In this embodiment, moreover, the protecting portion 116 is rolled on the inner wall 110a (i.e. toward the side facing the wearer M) from the lower edge 116a. With this configuration, the protecting portion 116 will unroll along the body of the wearer M when unrolling as can be seen in
In the wearable airbag device S3 in accordance with the third exemplary embodiment, furthermore, the airbag 110 in the form of the folded body 120 is stored in the outer cover 125 that includes the inner wall 126 that is adapted to face the wearer when worn and the outer wall 129 that is adapted to face away from the wearer when worn. The outer cover 125 will prevent the airbag 110 from being deployed toward a direction apart from the wearer M and guide the airbag 110 downward. The outer cover 125 will also improve an appearance of the wearable airbag device S3. If such an advantageous effect does not have to be considered, the wearable airbag device may be formed without an outer cover.
In the wearable airbag device S3 in accordance with the third exemplary embodiment, the lower end portion 126a of the inner wall 126 of the outer cover 125 and the lower end portion 129a of the outer wall 129 of the outer cover 125 are separably jointed together, and the lower end portion 126a of the inner wall 126 and the lower end portion 129a of the outer wall 129 are configured to be separated from one another by the airbag 110 and configured to lead the airbag 110 to deploy downward in an initial stage of airbag deployment. More specifically, Each of the inner wall 126 and outer wall 129 of the outer cover 125 includes, in the lower edge portion 126a/129a, the folded-in portion 127/130 that is folded inward. The folded-in portions 127 and 130 are configured to turn and extend downward in the initial stage of airbag deployment, and serve as the guide portion that leads the airbag 110 to deploy downward. This configuration prevents foreign matter from entering into the outer cover 125 from below. Further, the folded-in portions (i.e. the guide portions) 127, 130 further prevent the airbag 110 from floating away from the body of wearer M during deployment. If such advantageous effects do not have to be considered, the lower end portion of the outer cover may be left open so as to allow the airbag to deploy therefrom. Further alternatively, the outer cover may be formed without the folded-in portions though the lower end portions of the inner wall and outer wall are separably jointed together. Although the outer cover 125 of this embodiment including the folded-in portions 127, 130 is designed to cover approximately an upper half area of the bag body 113 of the airbag 110 as deployed, the outer cover may alternatively be formed so long as to cover substantially an entirety of the bag body as deployed to a vicinity of the lower end by elongating the folded-in portions.
The airbag may be configured like an airbag 140 depicted in
The airbag 140 is also stored in a not-shown outer cover in the form of a folded body, a form of the airbag 140 that has been folded and has a reduced width in an up and down direction compared to that in an unfolded state in which the inner wall 140a and the outer wall 140b are laid flat one over the another. More specifically, the airbag 140 is folded from the unfolded state as follows: an upper end portion of the airbag 140 composed of the contact portion 142 is folded in a concertina fashion on a plurality of creases extending in the front and rear direction (in other words, in the left and right direction of the airbag 140 as unfolded), while each of the protecting portions 143 is folded and reduced in width in the up and down direction. More particularly, each of the protecting portions 143 is folded firstly by a front-rear contracting folding that reduces the width in the left and right direction (i.e. in the front and rear direction in a worn state) of the protecting portion 143 as laid flat, then by an up-down contracting folding that reduces the width in the up and down direction of the protecting portion 143. As can be seen in
At deployment of the airbag 140 configured as described above, the contact portion 142 will be inflated first and push each of the protecting portions 143 downward, then each of the protecting portions 143 will be inflated while the rolled portion 150 unrolls (that is, the folds that were formed in the up-down contracting folding unfold) first, then the folds that were formed in the front-rear contracting folding unfold. Thus the protecting portions 143 cover the outer sides of the trochanters TP of femurs (i.e. the object of protection) quickly and amply in the up and down direction. The protecting portions 143 will be also prevented from being displaced with respect to the trochanters TP of femurs in the front and rear direction. In the airbag 140, especially, since a lower end portion of each of the protecting portions 143 is rolled on the inner wall 140a from the lower edge (from the lower edge 148a of the front-rear contracted bag 148) in the up-down contracting folding, this portion will unroll along the body of the wearer M and be prevented from floating away from the wearer M adequately. Moreover, each of the protecting portions 143 is stored in the not-shown outer cover in a form that is reduced in width in the front and rear direction. This configuration will avoid bulkiness. More particularly, since the rolled portion 150 formed by folding the protecting portion 143 is reduced in width in the front and rear direction to a substantially same width as that of the communication portion 144 as indicated with dashed-and-double-dotted lines in
With the wearable airbag devices S1 to S3 in accordance with the foregoing exemplary embodiments, the two protecting portions 16, 52, 116, 143 of the airbags 10, 10A, 10B, 50, 110, 140 are able to cover vicinities of bases of the femurs TB (i.e. the trochanters TP of femurs) of the wearer M in a steady fashion. That is, the wearable airbag devices S1 to S3 in accordance with the exemplary embodiments will help prevent fractures of the femur TB that may take a long time to treat, thus will be suitable for use by elderly people.
In the wearable airbag devices S1 and S3 in accordance with the foregoing exemplary embodiments, the airbag 10, 10A, 10B, 110 includes the two bag bodies 13, 13A, 13B, 113 that are connected by the gas-feeding path 12, 112 and configured to protect the left and right objects of protections (i.e. the trochanters TP of femurs). However, the structure of the airbag should not be limited thereby. The wearable airbag device may alternatively include two separate airbags each connected with a gas generator for protecting the left/right object of protection.
The wearable airbag devices of the above embodiments are each designed to have a belt shape so as to be put on around the hip. However, the application of the invention should not be limited to the disclosed embodiment. By way of example, the invention may be applied to a wearable airbag device which is formed into a vest, a jacket or the like for wearing on the torso and includes a folded airbag in a lower end portion.
An exemplary embodiment relates to a wearable airbag device adapted to be worn by a wearer for protecting the hip of the wearer. The airbag device includes an airbag that is adapted to be put on a circumference of the pelvis of the wearer and configured to be inflated with an inflation gas. The airbag includes: an inner wall that is configured to face the wearer at airbag deployment, the inner wall having a circumferential edge; an outer wall that is configured to face away from the wearer at airbag deployment, the outer wall having a circumferential edge jointed with the circumferential edge of the inner wall so that the airbag has a substantially board shape when inflated; a contact portion that is disposed in an upper reach of a stream of the inflation gas and is configured to be deployed at least at a side of the pelvis at airbag deployment; at least one protecting portion that is configured to be deployed in such a manner as to extend downward from the contact portion for covering an outer side of the trochanter of femur of the wearer at airbag deployment; and a float-preventing means that is configured to prevent the protecting portion from floating away from the body of the wearer at airbag deployment.
In the wearable airbag device in accordance with the above exemplary embodiment, although the protecting portion for covering an outer side of the trochanter of femur is configured to be deployed in such a manner as to extend downward from the contact portion disposed at a side of the pelvis, the float-preventing means prevents the protecting portion from floating away from the hip, in other words, helps deploy the protecting portion in proximity to an object of protection (i.e. the trochanter of femur). Therefore, the protecting portion is able to cover the outer side of the trochanter of femur as the object of protection quickly and adequately.
Therefore, the wearable airbag device in accordance with the exemplary embodiment is able to protect the hip of the wearer in a steady fashion.
In one or more embodiments, the float-preventing means may be composed of a tether that connects the inner wall and the outer wall at a vicinity of a border between the contact portion and the protecting portion inside the airbag. The tether is configured such that, in the airbag as laid flat, an inner joint that connects a first edge of the tether to the inner wall is disposed at a higher position than an outer joint that connects a second edge of the tether to the outer wall.
The tether will suppress the airbag from being inflated too thick. Further, the tether is arranged such that the inner joint to the inner wall is disposed at a higher position than the outer joint to the outer wall. In other words, the tether makes a substantial film length of a portion of the inner wall forming the contact portion shorter than that of a portion of the outer wall forming the contact portion, each measured from an upper end of the airbag. This configuration will help bend the airbag at the inner joint of the tether at airbag deployment so that the lower end of the protecting portion is directed inward, i.e. toward the wearer, thus prevent the protecting portion from floating away from the hip of the wearer adequately. Therefore, the protecting portion is able to cover the outer side of the trochanter of femur as the object of protection adequately.
In one or more embodiments, the float-preventing means may be composed of a tuck that is formed in a region of the contact portion in the inner wall so as to make a film length in an up and down direction of the inner wall shorter than that of the outer wall. The tuck will make the film length in the up and down direction of the inner wall shorter than that of the outer wall and help bend the inner wall at the tuck, thus help deploy the airbag so that the lower end portion of the airbag (i.e. the lower end portion of the protecting portion) is directed toward the wearer (i.e. inward). Further, since the tuck is formed in the region of the contact portion which is disposed in an upper portion of the airbag, the airbag will bend at the tuck so that a substantially entirety in the up and down direction of the protecting portion deploys in proximity to the wearer, thus prevent the protecting portion from being separated from the object of protection (i.e. the trochanter of femur) adequately, so that the protecting portion will cover the outer side of the object of protection adequately.
In one or more embodiments, the float-preventing means may be composed of a bulkhead that partitions the contact portion from the protecting portion inside the airbag in such a manner as to allow gas communication between the contact portion and the protecting portion. The protecting portion is configured to be inflated thinner than the contact portion at airbag deployment.
When the airbag configured as described above is deployed, the contact portion will be inflated with an inflation gas first, then the protecting portion will be inflated. The protecting portion will receive the inflation gas from the contact portion via the bulkhead since the protecting portion and the contact portion are partitioned by the bulkhead. Further, the protecting portion is configured to be inflated thinner than the contact portion at airbag deployment. The trochanter of femur as the object of protection is positioned farther outward in the left and right direction with respect to the center in a horizontal direction of the body of the wearer compared to the pelvis. The airbag is designed such that the protecting portion for covering the outer side of the trochanter of femur is thinner than the contact portion to be disposed at the side of the pelvis at airbag deployment. In other words, the protecting portion is deployed in such a manner as to be recessed relative to the contact portion. With this configuration, the difference in thickness between the contact portion and protecting portion absorbs the protrusion of the trochanter of femur from the pelvis, so that the protecting portion will be prevented from being deployed in such a manner as to open downward, in other words in such a manner that the lower end of the protecting portion is separated from the wearer. Therefore, the protecting portion will be prevented from floating away from the wearer adequately, thus cover the outer side of the object of protection (i.e. the trochanter of femur) adequately.
Another exemplary embodiment relates to a wearable airbag device adapted to be worn by a wearer for protecting the hip of the wearer, the airbag device including a gas generator; and an airbag that is adapted to be put on a circumference of the pelvis of the wearer and configured to be inflated with an inflation gas fed from the gas generator. The airbag includes: an inner wall that is configured to face the wearer at airbag deployment, the inner wall having a circumferential edge; an outer wall that is configured to face away from the wearer at airbag deployment, the outer wall having a circumferential edge jointed with the circumferential edge of the inner wall so that the airbag has a substantially board shape when inflated; an applying portion that is disposed in a vicinity of an upper end of the airbag and adapted to be applied to the circumference of the pelvis; two protecting portions each of which is configured to cover an outer side of the trochanter of femur of the wearer; a gas-feeding path that is connected with the gas generator and adapted to be disposed at the back of the pelvis; and two gas channels each of which provides gas communication between the gas-feeding path and each of the protecting portions, each of the gas channels extending downwardly and outwardly in a left and right direction from the gas-feeding path, then turning upward at a position beneath the protecting portion and communicating with the protecting portion by a leading end thereof.
In the wearable airbag device configured as described above, each of the protecting portions for covering outer sides of the trochanters of femurs is designed to receive an inflation gas for inflation from the lower side via the gas-feeding path and gas channel. With this configuration, the inflation gas will flow away from the center of the wearer in the gas channels, but turn and flow toward the center of the wearer when entering into the protecting portions since the airbag is mounted around the pelvis by the upper end portion. This flow of inflation gas inside the airbag will prevent the protecting portions from being separated from the wearer at airbag deployment, so that the airbag will be able to cover the outer sides of the object of protection (i.e. the trochanters of femurs) with the protecting portions adequately.
Yet another exemplary embodiment relates to a wearable airbag device adapted to be worn by a wearer for protecting the hip of the wearer, the airbag device including an airbag that is adapted to be put on a circumference of the pelvis of the wearer and configured to be inflated with an inflation gas. The airbag includes: an inner wall that is configured to face the wearer at airbag deployment, the inner wall having a circumferential edge; an outer wall that is configured to face away from the wearer at airbag deployment, the outer wall having a circumferential edge jointed with the circumferential edge of the inner wall so that the airbag has a substantially board shape when inflated; a contact portion that is disposed in a vicinity of an upper end of the airbag as deployed and configured to be deployed at least at a side of the pelvis; and at least one protecting portion that is configured to be deployed in such a manner as to extend downward from the contact portion for covering an outer side of the trochanter of femur of the wearer at airbag deployment. The airbag has a folded form that has a reduced width in an up and down direction compared to that of the airbag in an unfolded state in which the inner wall and outer wall are laid flat one over another. The folded form of the airbag is so configured as to allow the contact portion to be inflated prior to the protecting portion, and to push and deploy the protecting portion downward in an initial stage of airbag deployment.
In the wearable airbag device configured as described above, the airbag is configured so that the contact portion is inflated first and the contact portion as inflated pushes and deploys the protecting portion downward. This configuration will help deploy the protecting portion in a manner prevented from floating away from the wearer, in other words, in proximity to the object of protection, the trochanter of femur. Therefore, the protecting portion will be able to cover the outer side of the trochanter of femur as the object of protection quickly and adequately.
Therefore, the wearable airbag device in accordance with the above exemplary embodiment is able to protect the hip of the wearer in a steady fashion.
In one or more embodiments, the contact portion may be folded in a concertina fashion while the protecting portion is rolled from the lower edge. This configuration will help inflate the contact portion quickly so that the protecting portion will unfold and be deployed downward quickly.
In one or more embodiments, the protecting portion may be rolled on the inner wall from the lower edge. With this configuration, the protecting portion will unroll along the body of the wearer when unrolling, thus will be prevented from floating away from the body of the wearer further adequately.
In one or more embodiments, the wearable airbag device may be configured such that: the airbag further includes a communication portion that provides gas communication between the protecting portion and the contact portion; the protecting portion is configured to have a greater width in a front and rear direction than the communication portion when fully inflated; and the protecting portion has such a folded form that was formed through a front-rear contracting folding that folds and reduces a width in a front and rear direction of the protecting portion, and an up-down contracting folding that folds and reduces a width in the up and down direction of the protecting portion after the front-rear contracting folding.
At deployment of the airbag configured as described above, the contact portion will be inflated first and push the protecting portion downward, then the protecting portion will be inflated while unfolding in the up and down direction (that is, the folds that were formed in the up-down contracting folding unfold) first, then unfolding in the front and rear direction (that is, the folds that were formed in the front-rear contracting folding unfold). Thus the protecting portion will cover the outer side of the trochanter of femur (i.e. the object of protection) quickly and amply in the up and down direction. The protecting portion will also be prevented from being displaced with respect to the trochanter TP of femur in the front and rear direction. Moreover, in the wearable airbag device configured as described above, the protecting portion is reduced in width in the front and rear direction by folding. This configuration will avoid bulkiness.
In one or more embodiments, the wearable airbag device may further include an outer cover that covers an outer circumference of the airbag, the outer cover including an inner wall that is adapted to face the wearer when worn and an outer wall that is adapted to face away from the wearer when worn. The outer cover will prevent the airbag from being deployed toward a direction apart from the wearer and guide the airbag downward. The outer cover will also improve an appearance of the wearable airbag device.
In one or more embodiments, the outer cover may be configured such that a lower end portion of the inner wall and a lower end portion of the outer wall are separably jointed together, and such that the lower end portion of the inner wall and the lower end portion of the outer wall are configured to be separated from one another by the airbag and configured to lead the airbag to deploy downward in the initial stage of airbag deployment. This configuration will prevent foreign matter from entering into the outer cover from below, and also prevent the airbag from floating away from the body of wearer during deployment.
Number | Date | Country | Kind |
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2020-165664 | Sep 2020 | JP | national |
2020-165665 | Sep 2020 | JP | national |
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Entry |
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Office Action dated May 30, 2023 in corresponding Japanese Patent Application No. 2020-165664 (and English machine translation). |
Office Action dated May 30, 2023 in corresponding Japanese Patent Application No. 2020-165665 (and English machine translation). |
Number | Date | Country | |
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20220095711 A1 | Mar 2022 | US |