JP2005255061A - Shunt of squib - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve assembling workability of a shunt to a socket by sufficiently providing a holding force of the shunt by an inflater, preventing falling of the shunt from the inflater, and reducing insertion force of the shunt into a socket. <P>SOLUTION: The shunt 300 is provided with a short circuit piece 400 for short-circuiting a pair of pins 210 of a squib 200, the shunt body is provided with a projection 360 made of flexible material, and the base end of the projection is disposed on the outer surface of the shunt body. The projection extends, from the base end, in parallel with the center axis of the shunt body and in a tilted direction to the outside of the shunt body at an angle of 90° or less with respect to the direction pointing the top. The projection bends when the tip of the projection is pushed toward a connection hole 340 of the shunt body, and the projection returns and projects into an engaging recessed part 114 when the shunt body engages with the socket. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  An inflator that sends gas to an airbag and deploys the gas has a squib (a heating element). In order to supply electrical energy to the squib, a female connector is connected to a pair of pins on the squib. The present invention relates to a shunt in which a pair of pins of a squib is short-circuited until the female connector is connected to a pair of pins.

As this type of shunt, a shunt that fits into a socket that opens on the surface of the housing of the inflator and that is recessed in a cylindrical shape from the opening to the inside of the housing, and that shorts a pair of pins of the squib that rises from the bottom of the socket It has been known. The shunt includes a shunt body formed in a cylindrical shape so as to fit into a socket, and a short-circuit piece provided on the shunt body. When the shunt body fits into the socket, the short-circuit piece shorts the pair of pins of the squib to prevent the squib from malfunctioning. When this inflator is installed in a vehicle and a female connector is fitted to the shunt, the contact of the female connector is connected to the pair of pins of the squib, and the short-circuiting piece is pushed by the female connector to be separated from the pair of pins of the squib. As a result, the operation circuit of the squib is alive and the inflator can be operated. The socket disclosed in this publication is provided with an engaging recess that is recessed radially outward from the inner peripheral surface in a midway portion in the depth direction. The engaging recess engages with a claw provided on the locking piece of the female connector, thereby holding the female connector on the inflator (see, for example, Patent Document 1).
JP 2002-151181 A

  As a structure for holding such a shunt in the socket, it is conceivable to provide a bulging portion that bulges outward so as to fit in the engaging recess on the outer peripheral surface of the shunt body. In that case, when the shunt is inserted into the socket, the bulging portion moves toward the bottom of the socket while being pushed toward the center of the shunt by the inner peripheral surface of the socket, and reaches the depth of the engaging recess. Restore and fit into the engagement recess. In this case, the fitting depth of the bulging portion into the engaging concave portion is obtained by restoration from the compressive deformation of the bulging portion and the shunt body, and therefore has a very small dimension. Further, since the bulging portion is galvanized by friction with the inner peripheral surface of the socket while moving toward the bottom surface of the socket, this reduces the fitting depth of the bulging portion into the engaging recess. For this reason, a sufficient holding force of the shunt by the inflator cannot be obtained, and for example, a problem that the shunt falls off from the inflator during transportation occurs. In addition, if the fitting depth of the bulging portion into the engaging recess is small, there is little response at the time of fitting, and the so-called click feeling is poor, so it is difficult to confirm that the fitting has been done. For this reason, there may be an illusion that the fitting has been performed even though it is in a semi-fitted state that is not completely fitted. In such a case, the holding force of the shunt is hardly obtained by the inflator, and the shunt can be easily removed from the inflator. Will fall off. Further, when the shunt is fitted into the socket, the insertion force is increased due to the friction between the bulging portion and the inner peripheral surface of the socket, and the assembling workability is impaired.

  The present invention has been made paying attention to such points, and the object of the present invention is to provide a protrusion protruding obliquely on the outer surface of the shunt body, and when the shunt is inserted into the socket, the protrusion is bent and deformed. When the shunt body fits into the socket, the protrusions return and protrude into the engagement recesses, so that sufficient holding power of the shunt is obtained by the inflator. It is intended to improve the workability of assembling the shunt into the socket by preventing the drop and reducing the insertion force of the shunt into the socket.

  In order to achieve the above-mentioned object, the first aspect of the present invention opens to the surface of the housing of the inflator, and is recessed in a cylindrical shape from the opening to the inside of the housing. A shunt that fits into a socket having an engaging recess recessed into the socket and that short-circuits a pair of pins of the squib that rises from the bottom surface of the socket, is formed in a cylindrical shape so as to fit into the socket, When a pair of pins of the squib enters from the bottom side and a connection hole through which the female connector fits from the top side is provided, and when the shunt body is fitted in the socket When the female connector comes into contact with the pair of pins of the squib and the female connector is fitted into the connection hole, the short-circuit piece that is pushed by the female connector and separates from the pair of pins of the squib and a flexible material A protrusion formed on the shunt body, the base end of the protrusion being provided on the outer surface of the shunt body, and the protrusion from the base end in a direction parallel to the central axis of the shunt body and toward the top surface. It extends in a direction that falls outside the shunt body at an angle of 90 degrees or less, and when the tip of the protrusion is pushed toward the connection hole of the shunt body, the protrusion bends and the shunt body fits into the socket. In some cases, the projection is restored and protrudes into the engaging recess.

  When the shunt body is fitted into the socket, a pair of squib pins are inserted into the connection hole from the bottom surface side. At this time, since the short-circuit piece contacts both pins and short-circuits them, the squib does not function. When the female connector is fitted into the connection hole from the top surface side, the short-circuiting piece is pushed by the female connector and is separated from the pair of pins, and the contact of the female connector is connected to the pair of pins, whereby the operation circuit of the squib is The inflator can be activated alive.

  When assembling the shunt into the socket, when the shunt is inserted into the socket, the tip of the protrusion is pushed toward the connection hole of the shunt body by the inner peripheral surface of the socket, and the protrusion is bent and deformed to escape toward the connection hole. . In that case, since the protrusion is bent and deformed, a large displacement of the tip can be obtained with a small force as compared with compressive deformation of the bulging portion and the shunt body. Therefore, the frictional force acting on the protrusion and the inner peripheral surface of the socket is reduced as compared with providing the bulging portion on the outer peripheral surface of the shunt body. Accordingly, the insertion force of the shunt into the socket is reduced, and the workability of assembling the shunt into the socket is improved.

  When the shunt body is fitted into the socket, the protrusion is restored and protrudes into the engagement recess with a sufficient length. In addition, since the frictional force acting on the projection and the inner peripheral surface of the socket is reduced, the galling of the projection is reduced. Therefore, the engagement length of the protrusion with the engagement recess is sufficiently long, the holding power of the shunt by the inflator is improved, and the shunt is reliably prevented from falling off the inflator.

  When the protrusion protrudes into the engaging recess, the tip is largely deformed by restoring the protrusion from the bent state, so that a sufficient response occurs and a clear click feeling is obtained. Therefore, it is easy to confirm that the protrusion is engaged with the engaging recess, and the work is not finished in a half-engaged state where the protrusion is not completely engaged. Therefore, the holding power of the shunt by the inflator is improved and the shunt is prevented from falling off from the inflator.

  The squib shunt according to claim 2 is the squib shunt according to claim 1, wherein the shunt body is provided with a receiving recess recessed from the outer peripheral surface, the base end of the projection is provided in the receiving recess, and the tip of the projection is the shunt. When pushed toward the connection hole of the main body, the protrusion is bent and deformed so as to escape into the housing recess.

  In this way, when the tip of the projection is pushed toward the connection hole of the shunt body by the inner peripheral surface of the socket, the projection is bent and escapes into the housing recess. For this reason, even when the gap between the outer peripheral surface of the shunt body and the inner peripheral surface of the socket is small, the shunt body can be fitted into the socket.

  The shunt of the squib of claim 3 is the shunt of the squib of claim 1 or 2, wherein the tip of the protrusion has a tip of the socket, of the surface constituting the engagement recess when the shunt body is fitted to the socket. A regulating surface that contacts or faces the surface close to the opening is provided.

  In this way, even if the shunt body is about to come out of the socket after the shunt body is fitted into the socket, the restricting surface of the projection comes into contact with the surface of the engaging recess that is close to the socket opening. Since it is stretched, the holding power of the shunt by the inflator is further improved, and the shunt from the inflator is more reliably prevented.

  The shunt of the squib of claim 4 is the shunt of the squib of any one of claims 1 to 3, wherein the shunt body is engaged with the socket when the shunt body is fitted inside the tip of the protrusion. Also, a stopper that abuts on the inner peripheral surface of the socket closer to the socket opening is provided.

  In this way, even if the shunt body is about to come out of the socket after the shunt body is fitted into the socket, the tip of the protrusion touches and stretches against the surface that forms the engagement recess, and the stopper is further connected to the inner peripheral surface of the socket. Therefore, the holding power of the shunt by the inflator is further improved, and the protrusion is prevented from being excessively deformed. Further, since the stopper comes into contact with the inner peripheral surface of the socket, the response is increased and a larger click feeling can be obtained. Therefore, it becomes easier to confirm that the protrusion is engaged with the engaging recess, and the work is further prevented from being finished in the half-engaged state. Therefore, the holding power of the shunt by the inflator is further improved, and the shunt from the inflator is more reliably prevented.

  The squib shunt according to claim 5 is the squib shunt according to any one of claims 1 to 4, wherein when the shunt body is fitted to the socket outside the tip of the projection, A stopper that comes into contact with the inner part is provided.

  In this way, even if the shunt body is about to come out of the socket after the shunt body is fitted into the socket, the tip of the protrusion comes into contact with the surface forming the engagement recess, and the stopper further Since it contacts the inner part, the holding power of the shunt by the inflator is further improved, and the protrusion is prevented from being excessively deformed. In addition, since the stopper comes into contact with the inner part of the engaging recess, the response increases and a larger click feeling can be obtained. Therefore, it becomes easier to confirm that the protrusion is engaged with the engaging recess, and the work is further prevented from being finished in the half-engaged state. Therefore, the holding power of the shunt by the inflator is further improved, and the shunt from the inflator is more reliably prevented.

  The shunt of the squib of claim 1 is provided with a protrusion protruding obliquely on the outer surface of the shunt body, and when the shunt is inserted into the socket, the protrusion is bent and deformed to escape inward, and the protrusion is projected when the shunt body is fitted into the socket. Was restored to protrude into the engaging recess. Therefore, the engagement length of the protrusion with the engagement recess is sufficiently long, and the engagement of the protrusion with the engagement recess can be easily confirmed by the click feeling, thereby preventing half-engagement. Therefore, the holding power of the shunt by the inflator is improved, and the shunt can be reliably prevented from falling off the inflator. In addition, the insertion force of the shunt into the socket is reduced, and the workability of assembling the shunt into the socket can be improved.

  According to the second aspect, even when the gap between the outer peripheral surface of the shunt body and the inner peripheral surface of the socket is small, the shunt body can be fitted into the socket.

  According to the third aspect, since the restricting surface of the protrusion comes into contact with the surface of the engaging recess and is stretched, the holding power of the shunt by the inflator is further improved, and the shunt is prevented from falling off from the inflator more reliably. Can do.

  According to the fourth aspect of the present invention, since the stopper comes into contact with the inner peripheral surface of the socket, the holding power of the shunt by the inflator can be further improved and the protrusion can be prevented from being excessively deformed. Furthermore, the click feeling is further increased and the half-engagement is further prevented, the holding power of the shunt by the inflator is further improved, and the shunt can be further reliably prevented from falling off the inflator.

  According to the fifth aspect of the present invention, since the stopper is in contact with the inner part of the engaging recess, the holding power of the shunt by the inflator can be further improved, and the protrusion can be prevented from being excessively deformed. Furthermore, the click feeling is further increased and the half-engagement is further prevented, the holding power of the shunt by the inflator is further improved, and the shunt can be further reliably prevented from falling off the inflator.

  Embodiments of the squib shunt S according to the present invention will be described below. FIG. 1 shows the shunt S and its peripheral members according to the first embodiment. Reference numeral 100 denotes an inflator housing. A squib 200 that generates heat upon receiving electric energy is fixed inside the housing 100, and an ignition agent and a gas generating agent are disposed around the squib 200. A retracted airbag is housed on the back side of the inflator. When the squib 200 receives electric energy and generates heat, the igniter is ignited, whereby the gas generating agent generates gas, and this gas deploys the airbag.

  As shown in FIGS. 1 and 2, a socket 110 is provided in the housing 100 of the inflator. The socket 110 opens to the surface of the housing 100 and is recessed in a cylindrical shape from the opening 112 to the inside of the housing 100. In the socket 110, a direction parallel to the central axis of the cylinder and inward of the housing 100 is referred to as a depth direction (D1 in FIG. 2), and a direction along the radius of the cylinder is a radial direction (R1 in FIG. 2). The direction along the circumference of the cylinder is referred to as the circumferential direction (C1 in FIG. 1). An engaging recess 114 that is recessed from the inner peripheral surface 113 to the outside in the radial direction is provided in the middle portion of the socket 110 in the depth direction. The outer side in the radial direction means the side where the radius increases along the radial direction. As shown in FIG. 2, in this embodiment, the engaging recess 114 is continuous in the circumferential direction and has a groove shape. However, the engagement recess 114 may be formed in a hole shape so as not to be continuous in the circumferential direction, and the number of the engagement recess 114 at that time is arbitrary. As shown in FIGS. 2 and 7, the engagement recess 114 of this embodiment is formed so that the cross section of the engagement recess 114 is trapezoidal when the housing 100 is cut along a plane including the central axis of the socket 110. ing. This cross section includes a first surface 114a near the opening of the socket 110, a second surface 114b far from the opening 112 of the socket 110, and a third surface 114c that connects these two surfaces 114a and 114b at the back. It is configured. The first surface 114 a, which is a surface near the opening 112 of the socket 110, is inclined so as to approach the central axis of the column of the socket 110 toward the opening 112. However, the present invention does not limit the cross-sectional shape of the engaging recess 114 to this, and for example, a first surface that is a surface close to the opening of the socket and a second surface that is a surface far from the opening of the socket. Are substantially parallel to each other, and various embodiments are included such as a case where the cross-sectional shape is an arc shape. The squib 200 is fixed to a portion on the back side of the socket 110 in the housing 100 of the inflator. The squib 200 has a pair of pins 210 protruding from a built-in heater, and the pair of pins 210 rises from the bottom surface 111 toward the opening 112 of the socket at the center of the socket 110.

  A shunt S is fitted into the socket 110, and the shunt S short-circuits the pair of pins 210 of the squib 200. As shown in FIGS. 3 to 6, the shunt S includes a shunt body 300 and a short-circuit piece 400 provided on the shunt body 300.

  The shunt body 300 is formed in a cylindrical shape so as to be fitted into the socket 110 by an insulator. In this case, the basic shape may be a cylindrical shape, and some deformation is allowed. The direction along the central axis of the cylinder (D2 in FIG. 3), the direction along the radius of the cylinder (R2 in FIG. 3), and the direction along the circumference (C2 in FIG. 5) will be described. In the center of the shunt body 300, a connection hole 340 is provided that penetrates from the bottom surface 310 to the top surface 320 along the central axis of the cylinder. A pair of pins 210 of the squib 200 enters the connection hole 340 from the bottom surface side. The top surface side of the connection hole 340 is formed in a shape corresponding to the boss 520 of the female connector 500 so that the female connector 500 described later is fitted.

  The short-circuit piece 400 contacts the pair of pins 210 of the squib 200 when the shunt body 300 is fitted to the socket 110, and when the female connector 500 is fitted to the connection hole 340, the short-circuit piece 400 is pushed by the female connector 500. Away from the pin 210. The short-circuit piece 400 is formed of a conductor, and one end of the short-circuit piece 400 is fixed to a portion near the top surface 320 of the shunt body 300. Two contact pieces 420 bent in a substantially L shape branch from one end 410 of the short-circuit piece 400, and these contact pieces 420 are directed toward the bottom surface 310 along the shunt body 300, and the contact pieces 420 bend. As a result, the tip of the contact piece 420 is displaced laterally. When the shunt body 300 is fitted to the socket 110, the tips of the contact pieces 420 of the contact pieces 420 come into contact with the pair of pins 210, and both pins 210 are short-circuited via the short-circuit piece 400. When the boss 520 of the female connector 500 is fitted into the connection hole 340, the tip of the contact piece 420 is pushed by the boss 520 of the female connector 500 and is separated from the pair of pins 210, and the conduction between both the pins 210 is interrupted. Be drunk.

  The shunt body 300 is provided with a protrusion 360 formed of a flexible material. An example of the flexible material is a resin. The protrusion 360 may be formed of the same material as the shunt body 300, and the shunt body 300 and the protrusion 360 may be provided integrally. In this embodiment, four protrusions 360 are provided at substantially equal intervals in the circumferential direction, but this does not limit the number and arrangement of the protrusions 360 of the present invention. The protrusion 360 is formed in a rod shape. The base end of the protrusion 360 is provided on the outer surface of the shunt body 300. As shown in FIG. 7, the protrusion 360 is directed from the base end in a direction that is parallel to the central axis of the shunt body 300 and tilted to the outside of the shunt body 300 at an angle θ within 90 degrees from the direction toward the top surface 320. It extends. This outside refers to the side away from the central axis of the shunt body 300. In this case, it may be outside in the radial direction, or outside the axis that forms an angle with the radial direction when viewed from the direction of the central axis. When the tip of the projection 360 is pushed toward the connection hole 340 of the shunt body 300, the projection 360 is bent and deformed, and when the shunt body 300 is fitted into the socket 110, the projection 360 is restored and the engagement recess 114 is formed. It is configured to protrude inside.

  The shunt body 300 is provided with an accommodation recess 350 that is recessed from the outer peripheral surface 330 toward the connection hole 340. The housing recess 350 is provided to receive at least a part of the protrusion 360 when the protrusion 360 is bent and deformed toward the connection hole 340. The base end of the protrusion 360 is provided in the housing recess 350. The projection 360 is bent and deformed to escape into the housing recess 350 when the tip of the projection 360 is pushed toward the connection hole 340 of the shunt body 300.

  As shown in FIG. 7, when the shunt body 300 is fitted into the socket 110, the tip of the protrusion 360 contacts the first surface 114 a close to the opening 112 of the socket 110 among the surfaces constituting the engagement recess 114. Alternatively, a restricting surface 361 is provided.

  As shown in FIGS. 1, 8, and 9, the female connector 500 includes a box-shaped connector body 510, a prismatic boss 520 protruding from the bottom surface of the connector body 510, and the inside of the connector body 510 and the boss 520. And a contact 530 that opens a connection port at the tip of the boss 520. An electric wire W is connected to the contact 530, and the electric wire W is connected to control means for sending electric energy to the squib 200. The female connector 500 further includes locking pieces 540 protruding from the connector body 510 on both sides of the boss 520. A claw 541 protruding outward is provided at the tip of the locking piece 540. The female connector 500 further includes a slider 550 that passes through the connector body 510 and slides along the boss 520. The slider 550 includes a first wedge 551 that moves up and down along the front surface of the boss 520 that faces the contact piece 420 when the boss 520 is fitted in the connection hole 340, and the boss 520 and the locking piece 540. There is provided a second wedge 552 that moves up and down between and partially exposed from the window of the locking piece 540. The top surface of the slider 550 that protrudes to the top surface side of the connector main body 510 is formed in a planar shape to serve as a button 553. There are various other female connector structures. For example, the female connector 500 in which the locking piece 540 is separated from the connector main body 510 and integrated with the second wedge 552 is illustrated. At this time, pressing the button 553 causes the locking piece 540, the first wedge 551, and the second wedge 552 to slide simultaneously. The shunt of the present invention is also intended for a simpler female connector that does not include some or all of claws, locking pieces, sliders, wedges, buttons, and the like.

  In the shunt body 300, two U-shaped notches 370 are formed at positions facing each other across the central axis of the shunt body 300. When the female connector 500 is fitted into the shunt body 300, the locking piece 540 of the female connector 500 is fitted into the notch 370. The present invention includes embodiments of shunts that are not provided with such notches.

  Reference numeral 380 denotes two bosses provided on the outer side of the shunt body 300, and 115 denotes a cavity formed in a recess on the periphery of the opening 112 of the socket 110. The boss 380 is fitted into the cavity 115 so that the shunt body 300 is fitted. Is prevented from turning. The present invention includes shunt embodiments in which the shunt body is not provided with such bosses, and shunt embodiments directed to sockets without cavities.

  The operation and effect of the shunt S of the first embodiment will be described. As shown in FIG. 9, when the shunt body 300 is fitted into the socket 110, the pair of pins 210 of the squib 200 enters the connection hole 340 from the bottom surface side. At this time, since the short-circuit piece 400 contacts both pins 210 and short-circuits them, the squib 200 does not function. When the female connector 500 is fitted into the connection hole 340 from the top surface side, the short-circuit piece 400 is pushed by the female connector 500 and is separated from the pair of pins 210, and the female connector 500 is connected to the pair of pins 210. 200 operating circuits are alive and the inflator is enabled. That is, when the boss 520 of the female connector 500 is fitted into the connection hole 340 with the slider 550 pulled up to the top surface side of the connector main body 510, the contact 530 of the female connector 500 is connected to the pair of pins 210 and locked. The claw 541 of the piece 540 is engaged with the engaging recess 114 of the socket 110. Next, when the button 553 is pressed and the slider 550 is slid to the tip end side of the boss 520, the first wedge 551 pushes the contact piece 420 outward, so that the contact piece 420 is separated from the pair of pins 210, thereby operating the squib 200. The circuit lives. Further, since the second wedge 552 pushes the locking piece 540 of the female connector 500 outward, the claw 541 of the locking piece 540 is strongly engaged with the engaging recess 114 of the socket 110.

  When the shunt S is assembled to the socket 110, when the shunt body 300 is inserted into the socket 110, the tip of the projection 360 is pushed toward the connection hole 340 of the shunt body 300 by the inner peripheral surface 113 of the socket 110, and the projection 360 Bends and escapes toward the connection hole 340. In that case, since the protrusion is bent and deformed, compared to compressing deformation of the bulging portion 390 and the shunt body 300 'as in the comparative example of FIG. 14, a large displacement of the tip can be obtained with a small force. Therefore, the frictional force acting on the protrusion 360 and the inner peripheral surface 113 of the socket 110 is reduced as compared with providing the bulging portion 390 on the outer peripheral surface 330 ′ of the shunt body 300 ′. Thereby, the insertion force of the shunt S into the socket 110 is reduced, and the workability of assembling the shunt S into the socket 110 is improved.

  When the shunt body 300 is fitted into the socket 110, the projection 360 is restored and protrudes into the engagement recess 114 with a sufficient length. Moreover, since the frictional force acting on the protrusion 360 and the inner peripheral surface 113 of the socket 110 is reduced, the protrusion 360 is less likely to bite. Therefore, compared with the comparative example of FIG. 14, the engagement length of the protrusion 360 with the engagement recess 114 is sufficiently long, the holding power of the shunt S by the inflator is improved, and the shunt S is removed from the inflator. It is surely prevented.

  When the protrusion 360 protrudes into the engaging recess 114, the tip 360 is greatly deformed by restoring from the bent deformation state, so that a sufficient response is generated and a clear click occurs compared to the comparative example of FIG. A feeling is obtained. Therefore, it is easy to confirm that the protrusion 360 is engaged with the engaging recess 114, and the operation is not completed in a half-engaged state where the protrusion 360 is not completely engaged. Accordingly, the holding power of the shunt S by the inflator is improved, and the shunt S is reliably prevented from falling off the inflator.

  As for the protrusion in the shunt of the present invention, the base end may be provided on the outer surface of the shunt body. Therefore, the present invention includes an embodiment in which the base end of the protrusion 360 is provided on the outer peripheral surface 330 of the shunt body 300, like the shunt of the second embodiment shown in FIG. On the other hand, in the first embodiment, the accommodation recess 350 that is recessed from the outer peripheral surface 330 is provided in the shunt body 300, the base end of the projection 360 is provided in the accommodation recess 350, and the tip of the projection 360 is the connection hole 340 of the shunt body 300. The projection 360 is bent and deformed when it is pushed toward the housing recess 350, so that it escapes into the housing recess 350. In this way, when the tip of the protrusion 360 is pushed toward the connection hole 340 of the shunt body 300 by the inner peripheral surface 113 of the socket 110, the protrusion 360 is bent and deformed and escapes to the housing recess 350. Therefore, even when the gap between the outer peripheral surface 330 of the shunt main body 300 and the inner peripheral surface 113 of the socket 110 is small, the shunt main body 300 can be fitted into the socket 110.

  The present invention does not limit the tip shape of the protrusion. Therefore, the embodiment includes a protrusion whose tip is rounded like a hemisphere, and a protrusion whose tip is sharp. On the other hand, at the tip of the projection 360 of the first embodiment, when the shunt body 300 is fitted into the socket 110, the first surface 114a close to the opening 112 of the socket 110 among the surfaces constituting the engagement recess 114. A restricting surface 361 is provided in contact with or confronting the surface. In this way, even if the shunt body 300 is about to come out of the socket 110 after the shunt body 300 is fitted into the socket 110, the restricting surface 361 of the protrusion 360 contacts the first surface 114a of the engaging recess 114. Since it is stretched, the holding force of the shunt S by the inflator is further improved, and the shunt S is further reliably prevented from falling off the inflator.

  FIG. 11 shows the protrusion 360 of the shunt S of the third embodiment. This shunt S is different from the first embodiment only in the shape of the protrusion 360. In this shunt S, when the shunt main body 300 is fitted into the socket 110 inside the tip of the protrusion 360, a stopper that abuts the socket inner peripheral surface 113 closer to the opening 112 of the socket 110 than the engagement recess 114. 362 is provided protruding. In this way, even if the shunt main body 300 is about to come out of the socket 110 after the shunt main body 300 is fitted into the socket 110, the tip of the protrusion 360 is brought into contact with the first surface 114a that is the surface constituting the engaging recess 114. Since the stopper 362 comes into contact with the socket inner peripheral surface 113, the holding force of the shunt S by the inflator is further improved, and the protrusion 360 is prevented from being excessively deformed. Further, since the stopper 362 contacts the inner peripheral surface 113 of the socket, the response is increased and a larger click feeling can be obtained. Therefore, it becomes easier to confirm that the protrusion 360 is engaged with the engaging recess 114, and the work is further prevented from being finished in the half-engaged state. Therefore, the holding force of the shunt S by the inflator is further improved, and the shunt S is more reliably prevented from falling off the inflator.

  FIG. 12 shows the protrusion 360 of the shunt S of the fourth embodiment. This shunt S differs from the first embodiment only in the shape of the protrusions. In the shunt S, a stopper 363 is provided outside the tip of the protrusion 360 so as to come into contact with the inner part of the engaging recess 114 when the shunt body 300 is fitted into the socket 110. In this embodiment, the back part is illustrated by the 3rd surface 114c of the surfaces which comprise the engagement recessed part 114. FIG. The inner portion indicates the outer portion of the engagement recess 114 in the socket radial direction, and is not limited to the third surface 114c of the engagement recess 114 in this embodiment. In this way, even if the shunt main body 300 is about to come out of the socket 110 after the shunt main body 300 is fitted into the socket 110, the tip of the protrusion 360 is brought into contact with the first surface 114a that is the surface constituting the engaging recess 114. Since the stopper 363 contacts the third surface 114c, which is the back part of the engagement recess 114, the holding force of the shunt S by the inflator is further improved, and the protrusion 360 is prevented from being excessively deformed. The Further, the stopper 363 comes into contact with the third surface 114c, which is the back part of the engaging recess 114, so that the response increases and a greater click feeling is obtained. Therefore, it becomes easier to confirm that the protrusion 360 is engaged with the engaging recess 114, and the work is further prevented from being finished in the half-engaged state. Therefore, the holding force of the shunt S by the inflator is further improved, and the shunt S is more reliably prevented from falling off the inflator.

  FIG. 13 shows the protrusion 360 of the shunt S of the fifth embodiment. This shunt S is different from the first embodiment only in the shape of the protrusion 360. Here, the first surface 114 a, which is a surface close to the opening 112 of the socket 110 among the surfaces constituting the engaging recess 114, is formed so as to be orthogonal to the central axis of the cylinder of the socket 110. The restriction surface 361 at the tip of the projection 360 of the shunt S is formed to be parallel to the first surface 114 a that is a surface constituting the engagement recess 114.

It is a perspective view which isolate | separates and shows the housing of the inflator in 1st Embodiment, a shunt, and a female connector. It is sectional drawing when a shunt is fitted to the housing of the inflator of 1st Embodiment, and it cuts in the surface containing the central axis of a socket. The squib is not sectioned. It is a front view of the shunt of 1st Embodiment. It is a side view of the shunt of 1st Embodiment. It is a top view of the shunt of 1st Embodiment. It is a bottom view of the shunt of 1st Embodiment. It is an enlarged view which shows the protrusion of the shunt of 1st Embodiment, and the engagement recessed part of a socket. The engaging recess is a cross-sectional view taken along a plane including the central axis of the socket. It is a perspective view of a female connector. It is sectional drawing when a shunt is fitted to the housing of the inflator of 1st Embodiment, and it cuts in the surface containing the central axis of a socket. The squib is not sectioned. A female connector is fitted in the shunt, and the portion of the female connector that protrudes from the shunt is indicated by a virtual line. It is an enlarged view which shows the protrusion of the shunt of 2nd Embodiment, and the engagement recessed part of a socket. The engaging recess is a cross-sectional view taken along a plane including the central axis of the socket. It is an enlarged view which shows the protrusion of the shunt of 3rd Embodiment, and the engagement recessed part of a socket. The engaging recess is a cross-sectional view taken along a plane including the central axis of the socket. It is an enlarged view which shows the protrusion of the shunt of 4th Embodiment, and the engagement recessed part of a socket. The engaging recess is a cross-sectional view taken along a plane including the central axis of the socket. It is an enlarged view which shows the processus | protrusion of the shunt of 5th Embodiment, and the engagement recessed part of a socket. The engaging recess is a cross-sectional view taken along a plane including the central axis of the socket. It is sectional drawing when the shunt of a comparative example is fitted to the housing of an inflator, and it cuts in the surface containing the center axis | shaft of a socket. The squib is not sectioned.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Inflator housing 110 Socket 111 Bottom surface 112 Opening 113 Inner peripheral surface 114 Engaging recess 200 Squib 210 Pin S Shunt 300 Shunt body 310 Bottom surface 320 Top surface 330 Outer surface 340 Connection hole 350 Housing recess 360 Protrusion 361 Restricting surface 362 Stopper 363 Stopper 400 Shorting piece 500 Female connector

Claims (5)

Fits into a socket having an engagement recess that opens in the housing surface of the inflator, is recessed in a cylindrical shape inward from the opening, and indents in the depth direction from the inner peripheral surface to the outside in the radial direction And a shunt that shorts a pair of pins of the squib that rises from the bottom of the socket,
A shunt body that is formed in a cylindrical shape so as to fit into the socket, and in which a pair of pins of a squib enters from the bottom surface side and a connection hole through which a female connector fits from the top surface side is provided,
A short-circuit piece provided on the shunt body, which contacts the pair of pins of the squib when the shunt body is fitted into the socket, and is pushed by the female connector and separated from the pair of pins of the squib when the female connector is fitted into the connection hole. When,
A protrusion formed on the shunt body formed of a flexible material,
The base end of this protrusion is provided on the outer surface of the shunt body, and the protrusion is parallel to the central axis of the shunt body and tilted to the outside of the shunt body at an angle within 90 degrees from the direction toward the top surface. Extending to
The protrusion is bent and deformed when the tip of the protrusion is pushed toward the connection hole of the shunt body, and the protrusion is restored and protrudes into the engagement recess when the shunt body is fitted into the socket. A squib shunt characterized by     The shunt body is provided with an accommodation recess that is recessed from the outer peripheral surface, the proximal end of the projection is provided in the accommodation recess, and the projection is bent and deformed when the tip of the projection is pushed toward the connection hole of the shunt body. The squib shunt according to claim 1, wherein the shunt is configured to escape into the housing recess.     The front end of the protrusion is provided with a regulating surface that comes into contact with or confronts a surface close to the socket opening among the surfaces constituting the engaging recess when the shunt body is fitted into the socket. 2 squib shunts.     A stopper is provided on the inner side of the tip of the protrusion so as to protrude from the inner peripheral surface of the socket closer to the socket opening than the engaging recess when the shunt body is fitted into the socket. 4. The squib shunt of any one of items 3.     The squib shunt according to any one of claims 1 to 4, wherein a stopper is provided on the outer side of the tip of the protrusion so as to abut against the back of the engaging recess when the shunt body is fitted into the socket. .

Images