JP2010179883A - Seat for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a seat for a vehicle enabling the easy adjustment of the position of a lumber support. <P>SOLUTION: This seat 3 for the vehicle includes an active headrest 30 which operates a pressure receiving member 50 inside a seat back 20 when the occupant is sunk into the seat back 20 due to the momentum generated when the vehicle 1 is collided at the rear and projects the headrest 36 toward the rear head portion of the occupant by the operated pressure receiving member 50 and the lumber support 90 which is assembled inside the seat back 20 rotatably about an axis in the lateral direction so as to be able to support the lumber portion of the occupant. The pressure receiving member 50 comprises a sensor 55 capable of detecting the amount of operation of the pressure receiving member. When the amount of operation of the pressure receiving member detected by the sensor 55 is within the operating range by the initial load generated by the back rest of the occupant thereon, the rotation amount of the lumber support 90 is determined according to the amount of operation. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a vehicle seat, and more particularly, to a vehicle seat including an active headrest that projects a headrest toward the back of the occupant and a lumbar support that supports the lumbar portion of the occupant.

  Conventionally, when a rear collision occurs in a vehicle, there is already a headrest (so-called active headrest) that instantaneously jumps out a portion (support plate) that supports the back of the occupant toward the back of the occupant of the vehicle seat. Are known. Here, in Patent Document 1 below, a passenger seated in a vehicle seat sinks into the seat back due to a bounce when a rear collision occurs in the vehicle, thereby operating a pressure receiving member (pressure plate) inside the seat back. A technique for popping out a support plate by an actuated pressure receiving member is disclosed. Thereby, even when a rear collision occurs in the vehicle, it is possible to reduce the impact generated on the rear head of the occupant and improve safety. Moreover, the following patent document 2 discloses a technology provided with a lumbar support for supporting the lumbar portion of the occupant in addition to the technology for popping out the support plate described in the above-mentioned patent document 1.

JP 2007-314007 A JP 2002-345597 A

  However, in Patent Document 2 described above, the position adjustment of the lumbar support (adjusting the lumbar support by swinging the lumbar support so as to support the lumbar part at a position suitable for the physique in the sitting state) is performed by the passenger's own hand. It was a structure to be called. For this reason, this position adjustment is a troublesome work, and improvement has been demanded.

  The present invention is intended to solve such problems, and an object of the present invention is to provide a vehicle seat that can easily adjust the position of the lumbar support.

The present invention is for achieving the above object, and is configured as follows.
According to the first aspect of the present invention, the occupant sinks into the seat back due to the bounce when the rear collision occurs in the vehicle, and the pressure receiving member inside the seat back is operated, and the headrest is attached to the occupant by the operated pressure receiving member. An active headrest that jumps out toward the back of the head, a lumbar support that can support the lumbar vertebrae of the occupant seated back on the seat back, and can swing around the axis with the width direction in the seat back. If the operating amount detected by this sensor is within the operating range due to the initial load of the occupant's backrest, the vehicle seat provided with The swing amount of the lumbar support is determined according to the operation amount.
According to this configuration, the lumbar support can be swung according to the initial load of the occupant's backrest. Therefore, the lumbar support can be swung to a position that matches the occupant's physique without bothering the passenger. Therefore, it is possible to easily adjust the position of the lumbar support.

FIG. 1 is an overall perspective view of a vehicle to which a vehicle seat according to an embodiment of the present invention is applied. FIG. 2 is an overall perspective view showing a skeleton of the vehicle seat of FIG. FIG. 3 is an overall perspective view of the clutch mechanism of FIG. FIG. 4 is a schematic side view of the clutch mechanism of FIG. FIG. 5 is a schematic front view of the clutch mechanism of FIG. FIG. 6 is a diagram for explaining a state in which the initial load of the occupant's backrest is applied in FIG. FIG. 7 is a schematic side view illustrating the operation of the vehicle seat shown in FIG.

  Hereinafter, the form for implementing this invention is demonstrated using FIGS. In FIG. 2, in order to show the internal structure of the vehicle seat composed of the seat cushion 10, the seat back 20 and the active headrest 30 in an easy-to-understand manner, these cushion structure and skin structure are omitted, and only the internal frame structure is shown. Show. In the following description, the terms “up”, “down”, “front”, “back”, “left”, and “right” refer to the directions of “up”, “down”, “front”, “rear”, “left”, and “right” described in the above-described figures. When up, down, front, back, left, right are shown.

  First, a schematic configuration of a vehicle 1 according to an embodiment of the present invention will be described with reference to FIG. The vehicle 1 is, for example, a known passenger car, and includes a plurality of vehicle seats (a driver seat 2, a passenger seat 3, and a rear seat 4). In the following embodiments, the passenger seat 3 will be described as an example of the vehicle seat of the present invention.

  Next, the entire configuration of the passenger seat 3 will be described with reference to FIGS. Since the remaining seats (driver's seat 2 and rear seat 4) are known seats, detailed description thereof will be omitted. The passenger seat 3 includes a seat cushion 10 on which an occupant is seated, a seat back 20 that serves as a backrest portion of the seated occupant, and an active headrest 30 that supports the rear head of the seated occupant. Below, the internal structure of each of these component members 10, 20, and 30 will be described individually.

  First, the internal structure of the seat cushion 10 will be described. The interior of the seat cushion 10 includes a pair of left and right cushion frames 12, 12 that form the contour of the seat cushion 10, a front rod (not shown) that bridges the front portions of both the cushion frames 12, and both the cushion frames The rear rod 14 is configured to bridge the rear portion of the twelve. Moreover, the bracket 16 is assembled | attached to these both cushion frames 12 so that it may bridge | cross the approximate center of the front-back direction. The bracket 16 is assembled with a seat ECU 98, which will be described later, which is a computer that controls various electrical components (not shown) of the passenger seat 3.

  Next, the internal structure of the seat back 20 will be described. The interior of the seat back 20 also includes a pair of left and right side frames 22, 22 that form the outline of the seat back 20, an upper frame 24 that bridges the upper portions of the side frames 22, and lower portions of the side frames 22. It is composed of a lower frame 26 that looks like a bridge. The lower ends of both side frames 22 are assembled to the rear ends of both cushion frames 12 of the seat cushion 10 via a reclining mechanism (not shown). Thereby, the seat back 20 can be tilted with respect to the seat cushion 10, and the seat back 20 can be held at a desired tilt position within the tilt range.

  A pair of left and right holders 24a and 24a are assembled to the upper frame 24, respectively. Supports 24b capable of inserting and locking a pair of left and right stays 34, 34 of an active headrest 30, which will be described later, are assembled to both holders 24a. Thereby, the active headrest 30 can be assembled to the seat back 20.

  Of the two supports 24b, a rod 38 disposed inside one stay 34 (left stay 34 in FIG. 2) is provided inside one support 24b (left support 24b in FIG. 2). One end (upper end in FIG. 2) of the push-up operation cable 80 is inserted and locked. The operation cable 80 is a double-structured cable member composed of an outer cable 82 formed in a cylindrical shape and a wire-like inner cable 84 that is movably inserted into the outer cable 82. .

  Of the both ends of the operation cable 80, one end (the upper end in FIG. 2) of the outer cable 82 is inserted into the left support 24b as described above, and the other end of the outer cable 82 is inserted. An end portion (a lower end portion in FIG. 2) is hooked on a third rib 44 of a base plate 40 described later (see FIG. 3). On the other hand, one end portion (the upper end portion in FIG. 2) of the inner cable 84 is hooked and slidable in the vertical direction inside the left support 24b, and the other end portion of the inner cable 84 (FIG. 2). In FIG. 3, the lower end portion is hooked on a second swing member 75 described later (see FIG. 3).

  When a tension acts on the inner cable 84, one end of the outer cable 82 has a structure in which the rod 38 is pushed up to unlock the lock mechanism R of the active headrest 30 described later. The interior of the seat back 20 has such a structure.

  Finally, the internal structure of the active headrest 30 will be described. The inside of the active headrest 30 includes a base portion 32 that defines the active headrest 30, a pair of left and right stays 34 and 34 that are assembled integrally with the base portion 32, a tension spring and a link mechanism (both not shown) ), And the support plate 36 assembled through the above.

  Note that the support plate 36 is locked by the lock mechanism R so as to be substantially integrated with the base 32 against the urging force of the tension spring at a normal time before the rear collision occurs in the vehicle. When the lock mechanism R is unlocked, the link mechanism is actuated by the biasing force of the tension spring, so that the support plate 36 instantly protrudes forward from the base portion 32. Thereby, when tension acts on the inner cable 84, the occupant's rear head can be received instantaneously by the support plate 36. The inside of the active headrest 30 has such a structure.

  Subsequently, the clutch mechanism C and the lumbar support mechanism L assembled to the seat back 20 described above will be individually described. First, the clutch mechanism C will be described with reference to FIGS. The clutch mechanism C includes a base plate 40, a pressure receiving member 50, a connecting arm 60, a first swing member 70, and a second swing member 75. Below, each of these structural members 40, 50, 60, 70, and 75 will be described individually.

  First, the base plate 40 will be described. The base plate 40 is a member formed in a plate shape that forms the base of the clutch mechanism C. The base plate 40 is fastened to the front surface of the lower frame 26 (not shown in FIGS. 3 to 5).

  Next, the pressure receiving member 50 will be described. The pressure receiving member 50 is a member formed in a substantially plate shape so as to be able to receive a backrest load (especially a backrest load from the lumbar portion of the occupant) seated on the passenger seat 3. The pressure receiving member 50 is assembled to a pair of left and right first ribs 41 and 41 formed on the base plate 40 via a pin 51 so as to be rotatable about an axis whose axial direction is the vehicle width direction. At this time, the pressure receiving member 50 is biased via the torsion spring 52 in a direction (a direction indicated by an arrow A in FIG. 4) in which the tip of the pressure receiving member 50 contacts the back surface of the pad member P (not shown in FIG. 4) of the seat back 20. It is assembled in a state.

  In addition, the pressure receiving member 50 is assembled with an angle sensor 55 capable of detecting the amount of rotation. The angle sensor 55 is electrically connected to a seat ECU 98, which will be described later, via a cable 99. The pressure receiving member 50 is assembled so as not to interfere (contact) with a lumbar support 90 of a lumbar support mechanism L, which will be described later, no matter how the pin 51 rotates about the axis of the pin 51.

  Next, the connecting arm 60 will be described. The connecting arm 60 is a member formed in a substantially square shape that transmits only the backrest load from the occupant caused by the rear collision of the vehicle to the first swing member 70 described later. A pin 65 that can move inside the elongated hole 43 formed in the second rib 42 of the base plate 40 is formed at the substantially bent portion of the connecting arm 60. Further, a weight 64 is assembled to the distal end side of the connecting arm 60.

  The base end of the connecting arm 60 is assembled to a rib 54 formed on the pressure receiving member 50 via a pin 61 so as to be rotatable about an axis whose axial direction is the vehicle width direction. At this time, the connecting arm 60 is assembled in a biased state via the torsion spring 62 in the direction in which its own pin 65 contacts the front surface 43a of the long hole 43 (in the direction of arrow B in FIG. 4).

  Next, the first swing member 70 will be described. The first swing member 70 is a plate-shaped member that transmits the backrest load from the connecting arm 60 described above to the second swing member 75 described later. The first swing member 70 is assembled to the base plate 40 via a pin 71 so as to be rotatable about an axis whose axial direction is the direction perpendicular to the surface thereof. At this time, the first swinging member 70 is in a direction in which the protruding portion 70a formed so as to protrude from a part of the outer periphery contacts the fourth rib 45 formed on the base plate 40 (in FIG. C direction) is assembled in a biased state via a torsion spring 72.

  Further, the first swing member 70 is formed with a first arm 73 and a second arm 74 so as to protrude from a part of the outer periphery thereof. Ribs 73a and 74a are formed at the tips of both arms 73 and 74, respectively. Of these ribs 73a and 74a, the former rib 73a is formed so as to be pressed when the pin 65 of the connecting arm 60 is moved by a small backrest load, and the latter rib 74a has a large backrest. The pin 65 of the connecting arm 60 is formed so as to be pressed when it is moved by a load.

  Finally, the second swing member 75 will be described. The second swing member 75 is a member formed in a plate shape that pulls the operation cable 80 by a backrest load transmitted from the first swing member 70 described above. Similar to the first rocking member 70, the second rocking member 75 is assembled to the base plate 40 via a pin 76 so as to be rotatable about an axis whose vertical direction to the surface is the axial direction. ing.

  At this time, the second rocking member 75 has a torsion spring 77 in a direction (in the direction of arrow D in FIG. 5) in which the rib 78 formed on the outer circumferential surface thereof contacts the protruding portion 70a of the first rocking member 70. It is assembled in an energized state via. Further, as described above, the other end (lower end) of the inner cable 84 of the operation cable 80 is hooked on the second swing member 75. The clutch mechanism C is configured in this way.

  Next, the operation of the above-described clutch mechanism C will be described. First, in the state shown in FIG. 4, when the pressure-receiving member 50 receives a backrest load from the occupant via the pad member P of the seat back 20 by simply lining the back of the seat back 20, the connecting arm 60 rotates so that the pin 65 may move downward inside the long hole 43. At this time, the pin 65 of the connection arm 60 moves along the front surface 43 a in the elongated hole 43 by the biasing force of the torsion spring 62 acting on the connection arm 60.

  Also, from the state shown in FIG. 4, when the occupant gets on, or when the occupant tilts the seat back 20 backward (the reclining state) with his / her feet on the vehicle floor, When the pressure receiving member 50 receives a backrest load from the occupant, the connecting arm 60 rotates so that the pin 65 moves further downward in the elongated hole 43. Also at this time, the pin 65 of the connecting arm 60 moves along the front surface 43 a in the long hole 43 by the urging force of the torsion spring 62 acting on the connecting arm 60. Therefore, the backrest load caused by the occupant's riding or the backrest load caused by the occupant's simple backrest is not transmitted to the first swing member 70. The same applies to the backrest load caused by the rider.

  Further, as described above, when a rear impact occurs in the vehicle 1 from a state in which the occupant is backrested with respect to the seat back 20, the pressure receiving member 50 receives a backrest load from the occupant (to the vehicle). When the occupant seated on the passenger seat 3 sinks into the seat back 20 due to the momentum when the rear impact occurs, the pressure receiving member 50 receives a backrest load from the occupant), and the connecting arm 60 has a long pin 65. It rotates so that the inside of the hole 43 may move downward. At this time, since an inertial force acts on the weight 64 of the connecting arm 60 toward the rear due to the rear collision of the vehicle, the pin 65 of the connecting arm 60 is biased by the torsion spring 62 acting on the connecting arm 60. Against this, it moves along the rear surface 43b side in the long hole 43.

  Then, the pin 65 of the connecting arm 60 moves while pressing the rib 73a of the first arm 73 of the first swinging member 70, so that the pin 65 of the connecting arm 60 is moved by this movement. The first swing member 70 is rotated against the urging force. For this reason, the backrest load caused by the occurrence of a rear collision in the vehicle is transmitted to the first swing member 70.

  At this time, since the protruding portion 70a of the first swing member 70 presses the rib 78 of the second swing member 75, the second swing member 75 is also pressed by the torsion spring 77. It rotates against the urging force. Then, since the inner cable 84 of the operation cable 80 is pulled and tension is applied to the pulled inner cable 84, the lock mechanism R is unlocked as described above, and the support plate 36 is moved to the back of the occupant. Jump out to the side. This description is described in the claims. “The pressure-receiving member inside the seat back is actuated by the occupant sinking into the seat back due to the bounce when the rear collision occurs in the vehicle, and the headrest is operated by the actuated pressure-receiving member. Is equivalent to an “active headrest” that protrudes toward the back of the occupant.

  Of the backrest loads received by the pressure receiving member 50 described above, the backrest load received by the pressure receiving member 50 when the occupant simply backrests with respect to the seat back 20 (hereinafter simply referred to as “the pressure receiving member 50 receives”). "Initial load") corresponds to "Initial load of passenger's backrest" described in the claims. Here, the initial load will be described in detail. The initial load is a load that increases according to the physique of the occupant who sits back on the seat back 20. Therefore, as shown in FIG. 6, the pressure receiving member 50 rotates against the urging force of the torsion spring 52 according to the physique of the occupant who sits back on the seat back 20.

  In FIG. 6, the solid line of the pressure receiving member 50 indicates a state before the occupant rests on the seat back 20. Further, the imaginary line (1) of the pressure receiving member 50 is a case where the initial load is small, and shows a state where a small physique (for example, a woman, a child, etc.) is backrested with respect to the seat back 20. Yes. Further, the imaginary line (2) of the pressure receiving member 50 is a case where the initial load is medium, and a normal occupant (for example, a male having a weight of about 60 kg) simply leans back against the seat back 20. Indicates the state. Further, the imaginary line (3) of the pressure receiving member 50 is a case where the initial load is large, and shows a state in which a large occupant (for example, a male having a weight of about 80 kg) is simply backrested with respect to the seat back 20. ing.

  As is clear from FIG. 6, if the backrest load received by the pressure receiving member 50 is an initial load, the pin 65 of the connecting arm 60 is only the guide portion 43 c formed in the upper portion of the long hole 43. Move on. Therefore, if a rear collision occurs in the vehicle 1 after this movement, the pin 65 of the connecting arm 60 is not changed even if the initial load is small, the initial load is medium, or the initial load is large. The first rocking member 70 and the second rocking member 75 can also be rotated, and the tension can be applied to the inner cable 84 to allow the support plate 36 to jump out. Therefore, even when a physique difference occurs in the occupant, the influence due to the physique difference can be absorbed by the guide portion 43c of the long hole 43, and the clutch mechanism C can be reliably operated to pop out the support plate 36. it can.

  Next, returning to FIGS. 1 and 2, the lumbar support mechanism L will be described. The lumbar support mechanism L includes a lumbar support 90, a drive unit 92, a switch 96, and a seat ECU 98. Hereinafter, each of these structural members 90, 92, 96, and 98 will be described individually.

  First, the lumbar support 90 will be described. The lumbar support 90 is a support member that is eccentric in a crank shape so that a part of the lumbar support 90 can support the lumbar portion of the occupant seated on the passenger seat 3. Therefore, the lumbar support 90 is assembled to the upper side of the pressure receiving member 50 of the clutch mechanism C already described so that both ends of the lumbar support 90 can swing around both the side frames 22 of the seat back 20 about the axis whose axial direction is the vehicle width direction. It has been. The lumbar support 90 is assembled so that it does not interfere (contact) with each component of the clutch mechanism C no matter how it swings. The same applies to the pressure receiving member 50 of the clutch mechanism C as described above.

  Next, the drive unit 92 will be described. The drive unit 92 is a drive device that includes a motor (not shown) that swings the lumbar support 90 back and forth. Therefore, the drive unit 92 is assembled to one side frame (right side frame in FIG. 2) 22 while being mechanically fastened to one end (right end in FIG. 2) of the lumbar support 90. . Further, the drive unit 92 is provided with two limit switches (not shown) that electrically regulate the swing range of the lumbar support 90.

  Of these limit switches, one limit switch (hereinafter referred to as “front limit switch”) is a state in which the lumbar support 90 swings forward so as to support the lumbar portion of the occupant as much as possible (in FIG. 2, This is a state of the lumbar support 90 shown by an imaginary line, and it is provided so as to operate in the following simply referred to as “maximum support state”. On the other hand, the other limit switch (hereinafter referred to as “rear limit switch”), on the contrary, is in a state in which the lumbar support 90 swings to the rear as much as possible so as not to support the lumbar portion of the occupant (hereinafter referred to as “rear limit switch”). , Simply referred to as “unsupported state”).

  The drive unit 92 is electrically connected to a seat ECU 98, which will be described later, via a cable 99. Thus, the drive unit 92 can drive the motor based on the signal from the seat ECU 98 and swing the lumbar support 90 by a necessary amount. Accordingly, the seat ECU 98 described later can also detect whether the lumbar support 90 is in the maximum supported state or whether the lumbar support 90 is in the unsupported state.

  Next, the switch 96 will be described. The switch 96 is an operation member for manually driving the motor of the drive unit 92 described above. Therefore, this switch 96 is also electrically connected to a seat ECU 98, which will be described later, via a cable 99. Thereby, the seat ECU 98 can receive an operation signal from the switch 96. The switch 96 is assembled on the outer side surface (for example, a side panel) of the seat cushion 10 of the passenger seat 3. By operating the switch 96, the occupant can swing the lumbar support 90 in a range between a maximum support state and a non-support state. Thereby, the passenger | crew can support the position of the own lumbar part desired.

  Finally, the seat ECU 98 will be described. The seat ECU 98 is a control device that electrically controls the drive unit 92, the angle sensor 55, and the switch 96 described above. As already described, seat ECU 98 is electrically connected via angle sensor 55 and cable 99 (both not shown in FIG. 1). Thereby, the seat ECU 98 can receive the rotation amount of the pressure receiving member 50 from the angle sensor 55.

  In addition, when the front limit switch is operated, the seat ECU 98 can perform control to stop the lumbar support 90 from further swinging forward. On the contrary, when the rear limit switch is operated, the seat ECU 98 can perform control to stop the lumbar support 90 from swinging further rearward. Thereby, as described above, the lumbar support 90 can be electrically restricted from swinging beyond the swing range. The lumbar support mechanism L is configured in this way.

  Next, the operation of the passenger seat 3 will be described with reference to FIG. First, when the occupant M is seated on the passenger seat 3 from a state where the occupant M is not seated on the passenger seat 3 (shown by a solid line in FIG. 7), the pressure receiving member 50 is the pad of the seat back 20 as described above. The initial load starts to be received via the member P.

  At this time, when the physique of the occupant M is small (in FIG. 7, the occupant M is shown by an imaginary line (1)), the initial load is also small, so the pressure receiving member 50 is also in a small rotation state (the pressure receiving member in FIG. 50 is a state indicated by an imaginary line (1)). Then, as already described, this rotation amount is sent to the seat ECU 98, and the lumbar is transferred from the seat ECU 98 to the drive unit 92 so that the swing amount according to the sent rotation amount (small swing amount in this case) is obtained. A signal for swinging the support 90 is sent. Thereby, the lumbar support 90 can be swung by a small amount (in FIG. 7, the lumbar support 90 can be swung so as to be in a state indicated by an imaginary line (1)).

  At this time, when the occupant M has a medium physique (in FIG. 7, the occupant M is indicated by an imaginary line (2)), the initial load is also medium. It will be in a moving state (in FIG. 7, the pressure receiving member 50 is a state shown by an imaginary line (2)). Then, as in the case where the occupant M has a small physique as described above, the amount of rotation is sent to the seat ECU 98, and the amount of swing according to the amount of rotation sent (in this case, a moderate amount of swing). A signal for swinging the lumbar support 90 is sent from the seat ECU 98 to the drive unit 92. Thereby, the lumbar support 90 can be swung by an intermediate amount (in FIG. 7, the lumbar support 90 can be swung so as to be in a state indicated by an imaginary line (2)).

  At this time, when the occupant M has a large physique (in FIG. 7, the occupant M is indicated by an imaginary line (3)), the initial load is also large, so that the pressure receiving member 50 is also in a large rotation state ( The pressure receiving member 50 is in a state indicated by an imaginary line (3)). Then, when the physique of the occupant M is small, the amount of rotation is sent to the seat ECU 98 as in the case where the physique of the occupant M is medium, and the amount of swinging according to the amount of rotation sent (in this case, A signal for swinging the lumbar support 90 is sent from the seat ECU 98 to the drive unit 92 so that the swing amount is large). As a result, the lumbar support 90 can be swung by a large amount (in FIG. 7, the lumbar support 90 can be swung so as to be in a state indicated by an imaginary line (2)).

  It should be noted that these descriptions are as follows: “If the operating amount detected by this sensor is within the operating range due to the initial load of the occupant's backrest, the swing amount of the lumbar support is set according to the operating amount. Corresponds to “determined”. When the passenger M gets off the passenger seat 3, the rotation of the pressure receiving member 50 is returned by the urging force of the torsion spring 52. Therefore, along with this return, the swing of the lumbar support 90 is also returned. Then, when another occupant M is seated on the passenger seat 3, the lumbar support 90 swings again according to the initial load of the occupant M.

  The passenger seat 3 according to the embodiment of the present invention is configured as described above. According to this configuration, the lumbar support 90 can be swung according to the initial load of the passenger's backrest. Therefore, the lumbar support 90 can be swung to a position suitable for the occupant's physique without bothering the occupant. Therefore, the position adjustment of the lumbar support 90 can be easily performed. In addition, according to this configuration, the rotation amount of the pressure receiving member 50 in the region (the guide portion 43c of the long holes 43) that is not used when transmitting the backrest load of the occupant in the rotation region of the pressure receiving member 50 is reduced. Since the lumbar support 90 is swung by detection, this unused area can be used effectively.

The contents described above are only related to one embodiment of the present invention, and do not mean that the present invention is limited to the above contents.
In the embodiment, the passenger seat 3 has been described as an example of the vehicle seat. However, the present invention is not limited to this, and the driver seat 2 and the rear seat 4 may be used.

  In the embodiment, the seat ECU 98 of the passenger seat 3 has been described as an example of a computer that controls the drive unit 92. However, the present invention is not limited to this, and the main computer of the vehicle 1 may be used.

  Further, in the embodiment, the configuration in which the swing amount detection sensor for detecting the swing amount of the lumbar support 90 is not provided is described as an example. However, the present invention is not limited to this, and a configuration in which a swing amount detection sensor for detecting the swing amount of the lumbar support 90 may be provided. In this case, the feedback control is performed in which a signal is transmitted to the drive unit 92 based on the swing amount from the swing amount detection sensor. Thereby, the accuracy of the swing amount of the lumbar support 90 can be improved.

1 Vehicle 20 Seat back 30 Active headrest 50 Pressure receiving member 90 Lumber support

Claims (1)

An active headrest that activates a pressure receiving member inside the seat back when the occupant sinks into the seat back due to a bounce when a rear collision occurs in the vehicle, and causes the headrest to jump out toward the occupant's back of the head by the activated pressure receiving member When,
A lumbar support that is capable of supporting a lumbar portion of an occupant seated back on a seat back and swingable about an axis having a width direction as an axial direction inside the seat back; and a vehicle seat comprising:
It has a sensor that can detect the operating amount of the pressure receiving member,
A vehicular seat characterized in that the amount of rocking of the lumbar support is determined in accordance with the amount of operation if the amount of operation detected by the sensor is within an operating range due to the initial load of the occupant's backrest.

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