JP7338579B2 - pressure sensor device - Google Patents

Description

The present disclosure relates to a pressure sensor device that is attached to an opening in a wall.

Japanese Patent Application Laid-Open No. 2004-200002 discloses a mounting device for mounting in an opening provided in a wall of a vehicle. The device has a support element with a support nose and a retaining element with retaining wings for attaching the mounting device to the wall. The mounting device is such that for wall mounting the retaining element is rotatably arranged through the support element with respect to the support element and the support nose locks the support element against rotation. Furthermore, the support nose extends from the support element to a position beyond the outer edge of the retaining wing so as to act as an aid during fitting into the opening.

Then, after fitting the retaining wings with respect to the openings provided in the wall, the retaining wings are rotated so that the wall is clamped between the retaining wings and the support elements. In this way, the mounting device is adapted to be attached to the opening in the wall.

Japanese Patent No. 5579184

The inventors of the present invention have investigated making the mounting device function as a pressure sensor device by arranging the pressure detection section inside the holding element and forming a pressure introduction path for introducing pressure to the pressure detection section in the holding wing. are doing.

However, when the support nose is provided outside the outer edge of the holding wing as in Patent Document 1, the length of the holding wing is limited by the support nose, so the length of the pressure introduction path cannot be sufficiently secured. . If the length of the pressure introducing passage cannot be sufficiently ensured, foreign matter entering the pressure introducing passage tends to reach the vicinity of the pressure detecting portion, which is not preferable.

An object of the present disclosure is to provide a pressure sensor device capable of suppressing foreign matter from reaching the vicinity of the pressure detection unit.

The invention according to claim 1,
A pressure sensor device mounted against an opening (101) provided in a wall (100), comprising:
a support element (10) provided with a through hole (11);
a retaining element (20) having retaining wings (22) that can be fitted into the openings in the through holes;
a pressure sensing portion (30) arranged inside the retaining element,
In a fitted state in which the holding wing fitted in the through hole is fitted in the opening, the wall can be held between the holding wing and the support element by rotating the holding wing around the axis of the holding element,
The holding wing is formed with a pressure introduction passage (23) for introducing pressure to the pressure detection part,
The support element includes a rotation restricting portion (17) that restricts rotation of the support element,
Of the outer edges forming the edge of the opening, when the outermost edges (101d, 101e) are the positions farthest from the axis of the holding element in the above-described fitted state, the holding wings extend beyond the rotation restricting portion. including extensions (224, 225) extending near the outermost edge;
In the holding element, a pressure detecting portion is provided closer to the axis of the holding element than the rotation restricting portion, and the entrance (23a) of the pressure introducing passage is opened in the extending portion.

According to this, the inlet of the pressure introducing passage opens closer to the outermost edge of the opening than the rotation restricting portion, so that the length of the pressure introducing passage can be sufficiently secured as compared with the conventional case. For this reason, it becomes difficult for foreign matter that has entered the pressure introduction passage to reach the vicinity of the pressure detection section. That is, it is possible to realize a pressure sensor device capable of suppressing foreign matter from reaching the vicinity of the pressure sensing portion.

It should be noted that the reference numerals in parentheses attached to each component etc. indicate an example of the correspondence relationship between the component etc. and specific components etc. described in the embodiments described later.

1 is a schematic perspective view of a pressure sensor device according to an embodiment; FIG. 1 is a schematic side view of a pressure sensor device; FIG. FIG. 4A is a schematic front view of a wall containing an opening; 1 is a schematic exploded perspective view of a pressure sensor device; FIG. FIG. 4 is a schematic front view of a support element; FIG. 6 is a sectional view taken along line VI-VI of FIG. 5; FIG. 4 is a schematic front view of a retaining element; FIG. 8 is a cross-sectional view taken along line VIII-VIII of FIG. 7; FIG. 2 is a schematic cross-sectional view of the pressure sensor device in an exploded state; It is a top view which shows the state before attachment of a pressure sensor apparatus. 11 is a cross-sectional view taken along line XI-XI of FIG. 10; FIG. It is a top view which shows the state after attachment of a pressure sensor apparatus. 13 is a cross-sectional view taken along line XIII-XIII of FIG. 12; FIG. FIG. 10 is an explanatory diagram for explaining intrusion of foreign matter in the pressure sensor device of the comparative example;

An embodiment of the present disclosure will be described with reference to FIGS. 1-14. A pressure sensor device 1 shown in FIG. 1 is used to detect the operation of a side airbag for a vehicle. The pressure sensor device 1 is attached to an inner panel 100 attached to the inside of a side door of a vehicle, and outputs a detection signal corresponding to the pressure in the door interior space to be detected to an electronic control unit for an airbag (hereinafter referred to as an airbag ECU). called). Based on the detection signal from the pressure sensor device 1, the airbag ECU detects the pressure change in the interior space of the door that occurs when the door collides with the airbag, and activates the side airbag to protect the occupant. do.

As shown in FIG. 2, it is attached to the opening 101 provided in the inner panel 100 inside the side door. As shown in FIG. 3, the opening 101 has a circular portion 101a serving as a central portion and a pair of strip-shaped side portions 101b and 101c extending away from the center of the circular portion 101a. The pair of side portions 101b and 101c extend in opposite directions, and the circumferential width of the circular portion 101a is different from each other.

Outermost edge portions 101d and 101e of the opening 101 are formed on the opposite side of the circular portion 101a among the peripheral edge portions of the pair of side portions 101b and 101c. Outermost edge portions 101d and 101e are positioned furthest from the support shaft 221 of the holding element 20 in the fitted state where the pressure sensor device 1 is fitted in the opening portion 101 among the outer edge portions forming the edge of the opening portion 101. becomes.

Here, in this embodiment, the inner panel 100 corresponds to the wall on which the pressure sensor device 1 is mounted. As shown in FIG. 4, the pressure sensor device 1 has a support element 10, a holding element 20, a sensor IC 30, a printed circuit board 40, terminals 50, connectors 60, and the like.

The support element 10 is made of an insulating material such as resin. The support element 10 is constituted by a disc-shaped member. As shown in FIGS. 5 and 6, the support element 10 is formed with a through-hole 11 extending through the front and back at its central position. Retaining wings 22 formed on the retaining element 20 can be fitted into the through holes 11 . Moreover, the through hole 11 has the same shape as the opening 101 . The through hole 11 of the present embodiment has a substantially circular central hole portion 11a and a pair of belt-like side hole portions 11b and 11c extending away from the center of the central hole portion 11a. The through hole 11 has a central hole portion 11a having substantially the same shape as the circular portion 101a of the opening 101, and a pair of side holes 11b and 11c having substantially the same shape as the pair of side portions 101b and 101c. there is

The support element 10 has a first seal portion 12 and a second seal portion 13 formed outside the through hole 11 . Each of the first seal portion 12 and the second seal portion 13 has an annular shape surrounding the through hole 11 . Assuming that the side of the support element 10 on which the portion of the holding element 20 other than the holding wings 22 is arranged is the rear side, and the opposite side is the front side, the first seal portion 12 is provided on the front side of the support element 10, and the second seal is provided. A portion 13 is provided on the rear side of the support element 10 . The first seal portion 12 is provided to seal the gap between the inner panel 100 and the support element 10 when the pressure sensor device 1 is attached to the inner panel 100 . Also, the second seal portion 13 is provided to seal the gap between the support element 10 and the holding element 20 when the holding element 20 is attached to the support element 10 .

The outer diameter of the support element 10 is one size larger than the outer diameter of the plate portion 21 of the holding element 20 . A peripheral wall 15 is formed on the outer edge portion of the back side of the support element 10 and protrudes in the direction from the front side to the back side. As shown in FIGS. 1 and 2, the peripheral wall 15 is sized to allow a retaining element 20 to be arranged therein. Engagement claws 16 are formed on a portion of the peripheral wall 15 . When attaching the retaining element 20 to the supporting element 10 , the engaging claws 16 bring the supporting element 10 and the retaining element 20 together. It should be noted that relative rotation between the support element 10 and the holding element 20 is possible even after the support element 10 and the holding element 20 are integrated.

The support element 10 is provided with a rotation restricting portion 17 that restricts rotation of the support element 10 and a position restricting portion 18 that restricts displacement of the support element 10 in a direction that intersects the rotation direction RD of the support element 10 . The rotation restricting portion 17 and the position restricting portion 18 are formed on the peripheral edges of the pair of side holes 11b and 11c.

The rotation restricting portion 17 is provided in the support element 10 at a position overlapping the opening 101 so that it can be inserted into the opening 101 . The rotation restricting portion 17 is composed of rotation restricting pieces 17a and 17b projecting from the back side of the support element 10 toward the front side. The rotation restricting pieces 17a and 17b are formed at positions closer to the central hole portion 11a than the outer edges 11d and 11e of the side hole portions 11b and 11c among the peripheral portions of the pair of side hole portions 11b and 11c.

The rotation restriction 17 is configured so as not to interfere with the retaining wings 22 of the retaining element 20 . Specifically, as shown in FIGS. 9 and 11, the projection height of the rotation restricting pieces 17a and 17b is smaller than the distance between the plate portion 21 of the holding element 20 and the holding wing 22. As shown in FIG. The tip portions of the rotation restricting pieces 17a and 17b are slanted so that the projection height increases with increasing distance from the center of the central hole portion 11a.

The position restricting portion 18 is provided in the support element 10 at a position overlapping the opening 101 so that it can be inserted into the opening 101 . The position regulating portion 18 is composed of position regulating pieces 18a and 18b projecting from the back side of the support element 10 toward the front side. The position regulating pieces 18a, 18b are formed on the outer edges 11d, 11e of the side holes 11b, 11c among the peripheral edges of the pair of side holes 11b, 11c.

The position restraints 18 are configured so as not to interfere with the retaining wings 22 of the retaining element 20 . Specifically, as shown in FIGS. 9 and 11, the height of the protrusion of the position regulating pieces 18a and 18b is smaller than the distance between the plate portion 21 of the holding element 20 and the holding wing 22. As shown in FIG.

The holding element 20 is made of an insulating material such as resin. The holding element 20 integrally holds the sensor IC 30 , the printed circuit board 40 , the terminal 50 and the connector 60 . As shown in FIGS. 7 and 8 , the retaining element 20 has a plate portion 21 , retaining wings 22 and a connector mating portion 24 .

The plate portion 21 is configured by a disk-shaped member. The plate portion 21 has a structure in which the holding wing 22 is provided on the front side, with one side being the front side and the opposite side being the back side.

The retaining wings 22 can be fitted into the openings 101 while being fitted into the through holes 11 of the support element 10 . The holding wing 22 has a support shaft 221 , a first wing portion 222 and a second wing portion 223 .

The support shaft 221 is a member forming the shaft of the holding element 20 . The support shaft 221 is a substantially cylindrical member protruding from the back surface side toward the front surface side, and is disposed substantially in the center of the plate portion 21 . The outer diameter of the support shaft 221 has a shape corresponding to the circular portion 101a of the opening 101 (that is, substantially the same shape) so that it can be fitted into the circular portion 101a of the opening 101 . A first wing portion 222 and a second wing portion 223 are provided at the tip portion of the support shaft 221 .

The first wing portion 222 and the second wing portion 223 extend radially outward from the support shaft 221 . The first wing portion 222 and the second wing portion 223 extend in directions opposite to each other. The first wing portion 222 and the second wing portion 223 have shapes corresponding to the pair of side portions 101b and 101c of the opening 101 (that is, substantially similar shapes). The rear surfaces of the first wing portion 222 and the second wing portion 223 are inclined away from the plate portion 21 as they move away from the support shaft 221 so as not to interfere with the rotation restricting portion 17, the position restricting portion 18, and the like. ing.

Here, the holding wing 22 includes a first extending portion 224 and a second extending portion 225 extending beyond the rotation restricting portion 17 to near the outermost edge portions 101d and 101e.

The first extended portion 224 is a tip portion of the first wing portion 222 opposite to the support shaft 221 . The first extending portion 224 has a shape along the outermost edge portion 101d. Specifically, the first extended portion 224 has a concave shape with a recessed tip so as not to interfere with the position regulating portion 18 when the holding wing 22 is fitted into the through hole 11 of the support element 10 . Further, the width of the first extending portion 224 is larger than the portion of the support shaft 221 in the first wing portion 222 . The first extension portion 224 has a corner portion 224a at the tip that is shaped along the outermost edge portion 101d of the opening portion 101, so that it serves as a guide portion when the holding wing 22 is fitted into the opening portion 101. Function. A corner portion 224 a at the tip of the first extension portion 224 constitutes a fitting guide portion when fitting the holding wing 22 into the opening portion 101 .

The second extended portion 225 is a tip portion of the second wing portion 223 opposite to the support shaft 221 . The second extending portion 225 has a shape along the outermost edge portion 101e. Specifically, the second extended portion 225 has a concave shape with a recessed tip so as not to interfere with the position regulating portion 18 when the holding wing 22 is fitted into the through hole 11 of the support element 10 . In addition, the width of the second extension portion 225 is larger than the portion of the support shaft 221 in the second wing portion 223 . The corners 225a of the second extending portions 225 are shaped along the outermost edge portion 101e of the opening 101, so that they function as guides when the holding wings 22 are fitted into the opening 101. do. A corner portion 225 a at the tip of the second extension portion 225 constitutes a fitting guide portion when fitting the holding wing 22 into the opening portion 101 .

The holding wing 22 is formed with a pressure introducing path 23 for introducing the pressure in the inner space of the door to the sensor IC 30 arranged on the back side of the plate portion 21 . The pressure introduction path 23 is formed inside the first wing portion 222 and the support shaft 221 .

The pressure introduction path 23 extends along the axial direction of the support shaft 221 inside the support shaft 221 and extends along the radial direction of the support shaft 221 inside the first wing portion 222 . The pressure introduction path 23 opens to the central portion of the back side of the plate portion 21 on the support shaft 221 side, and opens to the tip portion of the first wing portion 222 on the first wing portion 222 side.

Specifically, in the holding element 20 , the sensor IC 30 is provided closer to the support shaft 221 than the rotation restricting portion 17 , and the inlet 23 a of the pressure introduction path 23 is opened to the first extending portion 224 . In other words, the inlet 23 a of the pressure introduction path 23 is formed radially outside the support shaft 221 relative to the rotation restricting portion 17 . As a result, as shown in FIG. 13, the channel length Lf from the support shaft 221 side of the pressure introduction channel 23 to the inlet 23a is longer than the length Lr from the support shaft 221 to the rotation restricting portion 17. As shown in FIG.

The holding element 20 is provided with a connector fitting portion 24 on the back side of the plate portion 21 . The connector fitting portion 24 is composed of a plurality of fitting pieces 241 for fitting the accommodating portion 61 of the connector 60 . The retaining element 20 and the connector 60 are integrated by fitting the receiving portion 61 into the connector fitting portion 24 .

Further, as shown in FIG. 1 and the like, the outer peripheral surface of the holding element 20 is formed with a protrusion 25 that constitutes a part of the rotation lock portion. When the holding element 20 is assembled to the support element 10 , the stops 19 provided on the peripheral wall 15 of the support element 10 can engage over the projections 25 so that the support element 10 and the holding element 20 are relative to each other. Rotation is locked.

After the retaining wings 22 have been fitted into the through-holes 11 of the support element 10 and the retaining element 20 is not rotated with respect to the support element 10 , the projections 25 are prevented from engaging the stops 19 . . When the holding element 20 is rotated relative to the support element 10 from this state, the stop 19 rides over the protrusion 25 and engages.

The sensor IC 30 is obtained by forming a pressure sensor element on a semiconductor chip. The sensor IC 30 is arranged inside the connector mating portion 24 of the holding element 20 . The sensor IC 30 is a pressure sensing portion arranged inside the holding element 20 . The sensor IC 30 is arranged closer to the axis of the holding element 20 than the rotation restricting portion 17 in the holding element 20 . Specifically, the sensor IC 30 is positioned on the back side of the support shaft 221 of the holding element 20 at the approximate center.

The sensor IC 30 outputs a signal corresponding to the pressure inside the door. The sensor IC 30 is mounted on the printed circuit board 40 and electrically connected to the terminal 50 through the printed circuit board 40 , so that signals from the sensor IC 30 are transmitted to the external airbag ECU through the terminal 50 .

The printed circuit board 40 mounts the sensor IC 30 and is electrically connected to the terminal 50, and has wiring patterns and the like forming an electric circuit (not shown) formed thereon. Each part of the sensor IC 30 is electrically connected to the printed circuit board 40 by, for example, wire bonding. A signal processing unit of the sensor IC 30 is mounted on the sensor IC 30 or the printed circuit board 40 .

The terminal 50 electrically connects the pressure sensor device 1 to the outside, and is connected to a desired position of the wiring pattern formed on the printed circuit board 40 . Terminals 50 are for power supply, ground (that is, GND), signal output, and the like.

The connector 60 is a hollow member forming a casing that accommodates the sensor IC 30 , printed circuit board 40 and terminal 50 . The connector 60 is made of, for example, a hard insulating resin material. The connector 60 enables electrical connection between the sensor IC 30 and the outside through the terminal 50 by being connected to an external connector (not shown).

Specifically, the connector 60 has a substantially rectangular accommodating portion 61 and a substantially cylindrical connector case 62 . The housing portion 61 and the connector case 62 of the connector 60 are arranged in the same direction as the direction in which the support shaft 221 and the first wing portions 222 are arranged.

The accommodating portion 61 is hollow, and the upper side (that is, one surface on the holding element 20 side) is open. A sensor IC 30 and a printed circuit board 40 are accommodated in this opened portion. Also, the pressure introduction path 23 of the holding wing 22 communicates with the inside of the housing portion 61 , and the pressure of the door inner space is introduced into the inside of the housing portion 61 .

In addition, although not shown, the housing portion 61 is formed with a partition wall to which the printed circuit board 40 is brought into close contact. The partition wall and the printed circuit board 40 airtightly partition the inside of the accommodating portion 61 into a space for arranging the sensor IC 30 and a space on the connector case 62 side. As a result, when the pressure in the door interior space is introduced into the installation space of the sensor IC 30 through the pressure introduction path 23 , the pressure in the door interior space acts on the sensor IC 30 without leaking into the space of the connector case 62 . Note that the placement space of the sensor IC 30 may be filled with the atmosphere, or may be filled with a filler. In this case, the pressure inside the door acts on the sensor IC 30 via the filler.

One end of the terminal 50 described above is inserted into a through hole (not shown) formed in the printed circuit board 40 and soldered to fill the through hole, thereby connecting to the printed circuit board 40 . Since the terminal 50 is bent in an L shape, the other end side of the terminal 50 extends toward the connector case 62 side.

The connector case 62 is connected to the housing portion 61 . The other end of the terminal 50 is arranged inside the connector case 62 . By connecting an external connector to the connector case 62 , the sensor IC 30 can be electrically connected to the outside through the terminal 50 .

Next, the attachment of the pressure sensor device 1 configured as described above to the inner panel 100 will be described.

A holding element 20 integrating a sensor IC 30 , a printed circuit board 40 , a terminal 50 and a connector 60 is fitted into the support element 10 . Specifically, as shown in FIGS. 4 and 9 , the retaining wings 22 of the retaining element 20 are aligned with the through holes 11 of the support element 10 and the retaining wings 22 are fitted into the through holes 11 .

Then, when the outer circumference of the holding element 20 pushes away the engaging claws 16 of the support element 10 and is fitted into the peripheral wall 15 , the engaging claws 16 return to their original positions due to the elastic force, and the end faces of the holding element 20 move. Get caught. This brings together the holding element 20 and the support element 10, as shown in FIGS.

In this state, as shown in FIG. 9, the holding wings 22 fitted in the through holes 11 are fitted into the openings 101 . Corners 224 a and 225 a at the tips of the extended portions 224 and 225 of the holding wings 22 of the present embodiment are shaped along the outermost edges 101 d and 101 e of the opening 101 . Therefore, when the holding wing 22 fitted in the through hole 11 is fitted into the opening 101 , the corners 224 a and 225 a of the extensions 224 and 225 do not fit when the holding wing 22 is fitted into the opening 101 . It functions as a mating guide. This makes it possible to easily fit the holding wing 22 into the opening 101 .

After that, the retaining wings 22 are rotated about the axis of the retaining element 20 in the fitted state in which the retaining wings 22 are fitted in the openings 101 . For example, the retaining element 20 is rotated in the direction indicated by arrow "RD" in FIG. At this time, the support element 10 is restricted from being displaced in the rotational direction RD by the rotation restricting portion 17 . Therefore, when the holding element 20 is rotated in the direction of rotation RD, the holding element 20 rotates while the support element 10 remains stationary, as shown in FIG.

When the retaining element 20 is rotated with respect to the supporting element 10, the inner panel 100 is clamped between the supporting element 10 and the retaining wings 22, as shown in FIG. Thereby, the pressure sensor device 1 is attached to the opening 101 of the inner panel 100 . By connecting an external connector to the connector 60 , the sensor IC 30 and the outside are electrically connected via the terminal 50 .

In the pressure sensor device 1 described above, when the holding wing 22 is rotated in a fitted state in which the holding wing 22 is fitted into the through hole 11 of the supporting element 10 and is fitted into the opening 101, the holding wing 22 and the supporting element are rotated. The inner panel 100 is sandwiched at 10 .

Here, FIG. 14 is a schematic cross-sectional view of a pressure sensor device CE serving as a comparative example of this embodiment. The pressure sensor device CE of the comparative example differs from the pressure sensor device 1 of the present embodiment in that the length of the first wing portions 222 of the holding wings 22 is short.

As shown in the comparative example of FIG. 14, if the length of the holding wing 22 is short, the length of the pressure introduction passage 23 cannot be sufficiently secured, and foreign matter (for example, water) entering the pressure introduction passage 23 becomes likely to reach the vicinity of the sensor IC 30, which is the pressure detection unit. When the foreign matter that has entered the pressure introduction passage 23 reaches the vicinity of the sensor IC 30 that is the pressure detection portion, the sensor IC 30 is likely to be wet or the pressure introduction passage 23 is likely to be blocked.

On the other hand, in the pressure sensor device 1 of the present embodiment, the holding wing 22 extends beyond the rotation restricting portion 17 to near the outermost edges 101d and 101e of the opening 101. A setting portion 225 is included.

In the pressure sensor device 1 , the sensor IC 30 is provided closer to the axis of the holding element 20 than the rotation restricting portion 17 in the holding element 20 , and the extension portions 224 and 225 are provided with the inlets 23 a of the pressure introduction paths 23 . is open. According to this, the inlet 23a of the pressure introduction passage 23 opens closer to the outermost edges 101d and 101e of the opening 101 than the rotation restricting portion 17, so the length of the pressure introduction passage 23 is reduced compared to the conventional art. can be sufficiently secured. Therefore, as shown in FIG. 13, it becomes difficult for foreign matter that has entered the pressure introducing path 23 to reach the vicinity of the sensor IC 30 . That is, it is possible to realize the pressure sensor device 1 capable of suppressing foreign matter from reaching the vicinity of the sensor IC 30 . For example, it is possible to prevent blockage of the pressure introduction passage 23 caused by water splashing in the door interior space.

In addition, since the corners 224a and 225a at the ends of the extensions 224 and 225 are shaped along the outermost edge 101d of the opening 101, when the holding wing 22 is fitted into the opening 101 It functions as a fitting guide part of. In this way, if the fitting guide portions are provided for the extension portions 224 and 225 of the holding wings 22 instead of the support element 10, the length of the pressure introduction path 23 can be secured and the opening of the holding wings 22 can be minimized. Fitting to the portion 101 can be easily performed.

Here, when inserting/removing the external connector, a force acts on the holding element 20 and the support element 10 in the insertion/removal direction of the external connector. That is, a force acts on the support element 10 and the like not only in the rotation direction RD of the holding element 20 but also in the cross direction crossing the rotation direction RD.

On the other hand, the support element 10 is provided with a position restricting portion 18 . According to this, the displacement of the support element 10 in the direction intersecting with the rotation direction RD is suppressed by the position regulating portion 18, so that the support element 10 can be properly fitted into the opening 101 and the mounting state of the support element 10 can be changed. can be maintained in proper condition.

(Other embodiments)
Although representative embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and can be modified in various ways, for example, as follows.

In the above-described embodiment, a specific example of the rotation restricting portion 17 was exemplified, but the rotation restricting portion 17 is not limited to that shown in the above-described embodiment, and is different from the above-described embodiment. may

In the above-described embodiment, specific examples were given as the extensions 224 and 225, but the extensions 224 and 225 are not limited to those illustrated in the above-described embodiment. can be different.

In the above-described embodiment, the corners 224a and 225a of the extensions 224 and 225 function as fitting guides when fitting the holding wing 22 into the opening 101, but the holding wing 22 may differ from the embodiments described above. Note that the corners 224a and 225a of the extensions 224 and 225 are not essential components and may be omitted.

In the above-described embodiment, a specific example of the position regulating portion 18 was exemplified, but the position regulating portion 18 is not limited to that shown in the above-described embodiment, and is different from the above-described embodiment. may Note that the position restricting portion 18 is not an essential component and may be omitted.

In the above-described embodiment, the pressure sensor device 1 is used for detecting the operation of a side airbag for a vehicle, but the pressure sensor device 1 can also be used for purposes other than detecting the operation of a side airbag for a vehicle. is.

In the above-described embodiments, it goes without saying that the elements that make up the embodiments are not necessarily essential unless explicitly stated as essential or clearly considered essential in principle.

In the above-described embodiments, when numerical values such as the number, numerical value, amount, range, etc. of the constituent elements of the embodiment are mentioned, when it is explicitly stated that they are essential, and in principle they are clearly limited to a specific number It is not limited to that particular number, unless otherwise specified.

In the above-described embodiments, when referring to the shape, positional relationship, etc. of components, etc., the shape, positional relationship, etc., unless otherwise specified or limited in principle to a specific shape, positional relationship, etc. etc. is not limited.

Reference Signs List 1 pressure sensor device 10 support element 11 through hole 20 holding element 22 holding wing 224 first extension (extension)
225 second extension (extension)
23 pressure introduction path 100 inner panel 101 opening

Claims (3)

A pressure sensor device mounted against an opening (101) provided in a wall (100), comprising:
a support element (10) provided with a through hole (11);
a retaining element (20) having retaining wings (22) that can be fitted into the openings in the through holes;
a pressure sensing portion (30) arranged inside the retaining element,
In a fitted state in which the retaining wings fitted in the through holes are fitted in the openings, the retaining wings are rotated around the axes of the retaining elements so that the walls are supported by the retaining wings and the support elements. It can be clamped,
The holding wing is formed with a pressure introduction path (23) for introducing pressure to the pressure detection part,
The support element includes a rotation restricting portion (17) that restricts rotation of the support element,
Of the outer edge portions forming the edge of the opening, when the outermost edge portions (101d, 101e) are the positions farthest from the axis of the holding element in the fitted state, the holding wing is positioned at the rotation restricting portion. extensions (224, 225) extending beyond the outermost edge to near the outermost edge;
In the holding element, the pressure detection part is provided closer to the axis of the holding element than the rotation restricting part, and the entrance (23a) of the pressure introducing passage opens to the extension part. sensor device. 2. The pressure sensor device according to claim 1, wherein said extended portion is formed with fitting guide portions (224a, 225a) for fitting said holding wing into said opening. 2. The supporting element is provided with a position restricting portion (18) for restricting displacement of the supporting element in a direction intersecting with the rotating direction of the holding wing at the periphery of the through hole. 3. The pressure sensor device according to 2.

Images