JP6079885B2 - Grab box - Google Patents

Description

  The present invention relates to an on-vehicle grab box.

  Various types of grab boxes are known which are disposed on an instrument panel of a vehicle. A general grab box includes a case portion and a grabrid. The case portion has a box shape, and the position of the grabrid changes with respect to the case portion. Specifically, the grabrid opens and closes the opening of the case portion. When the glide opens the opening of the case portion (that is, when the glide is placed in the open position), the inside of the case portion is exposed to the outside. In other words, the grab box is opened at this time. Further, when the gloved closes the opening of the case part (that is, when the gloved is disposed at the closed position), the inside of the case part is isolated from the outside. In other words, the grab box is closed at this time.

  By the way, a general grab box is provided with a lock mechanism for locking the grab lid in the closed position. The lock mechanism in this type of grab box locks the grabrid to the case portion. This lock can be released. As a lock mechanism, a saddle type as introduced in Patent Document 1 is generally used. The lock mechanism introduced in Patent Document 1 includes two movable side engaging portions that can reciprocate, a knob-like input portion, and an input portion that moves the input portion to each movable side engaging portion. A link mechanism for transmitting, and two fixed-side engaging portions respectively corresponding to the two movable-side engaging portions. Each movable side engaging part is provided in the gloved, and each fixed side engaging part is provided in the case part. When the user operates the operation knob, the link mechanism operates to operate the two movable side engaging portions, and the movable side engaging portion and the fixed side engaging portion engage with each other. The engagement is released. By the way, there is a variation in the relative positions of one movable side engaging portion (referred to as a first movable side engaging portion) and one fixed side engaging portion (referred to as a first fixed side engaging portion) for some reason. It is conceivable that the distance between the first movable side engaging portion and the first fixed side engaging portion is larger than the target value. In such a case, the engagement margin between the first movable side engaging portion and the first fixed side engaging portion is not sufficient, and the first movable side engaging portion and the first fixed side engaging portion are stable. It becomes difficult to engage. As a result, the locking performance of the grabrid by the lock mechanism may not be sufficient.

JP 2006-51904 A

  The present invention has been made in view of the above circumstances, and provides a grab box having a hook-type lock mechanism that locks a grab lid in a closed position by two movable side engaging portions, and has excellent locking performance. For the purpose.

The grab box of the present invention that solves the above problems is a box-shaped case part having an opening,
A glide that is displaceable relative to the case portion and can be placed in a closed position to close the opening;
A locking mechanism for locking the grabrid in the closed position,
The locking mechanism is
A first fixed-side engaging portion provided on one of the case portion and the grabrid; and a first movable-side engaging portion provided on the other of the case portion and the grabrid. A first engaging portion,
A second fixed-side engaging portion provided on one of the case portion and the grabrid; and a second movable-side engaging portion provided on the other of the case portion and the grabrid. A second engaging portion,
An input unit capable of changing a state relative to the grabrid;
A conversion unit that connects the input unit, the first movable side engagement unit, and the second movable side engagement unit;
The first movable side engaging portion includes a first lock position that engages with the first fixed side engaging portion, and a first release position that releases the engagement with the first fixed side engaging portion. Can slide between
The second movable side engaging portion includes a second lock position that engages with the second fixed side engaging portion, and a second release position that releases the engagement with the second fixed side engaging portion. Can slide between
In the converting portion, the sliding amount of the first movable side engaging portion between the first lock position and the first release position is such that the slide amount between the second lock position and the second release position is the same. The operation of the input part is transmitted to the first movable side engaging part and the second movable side engaging part so as to be larger than the sliding amount of the two movable side engaging parts.

The grab box of the present invention preferably includes any one of the following (1) to (5), and more preferably includes a plurality.
(1) The conversion unit includes a rotating body,
The first movable side engagement portion includes a first connection portion connected to the conversion portion,
The second movable side engaging portion includes a second connecting portion connected to the converting portion,
The rotating body is directly or indirectly connected to a rotating shaft, a first rotation connecting portion that is directly or indirectly connected to the first movable side engaging portion, and the second movable side engaging portion. A first rotation connecting portion,
The distance between the rotating shaft of the rotating body and the first connecting portion is longer than the distance between the rotating shaft and the second connecting portion.
(2) The conversion unit includes a rotating body,
The rotating body includes a rotation shaft, a first rotation connection portion positioned on the radially outer side of the rotation shaft, and a second rotation connection spaced apart from the first rotation connection portion and positioned on the radially outer side of the rotation shaft. Have a department
The first movable side engagement portion includes a first connection portion connected to the first rotation connection portion,
The second movable side engagement portion includes a second connection portion connected to the second rotation connection portion,
The distance between the rotation shaft of the rotating body and the first rotation connection portion and the distance between the rotation shaft and the second rotation connection portion are the same,
When moving between the first lock position and the first release position, the linear movement distance of the first rotation connecting portion in the sliding direction of the first movable side engaging portion is the second lock position. 2. The grab box according to claim 1, wherein the grab box is larger than a linear movement distance of the second rotation connecting portion in a sliding direction of the second movable side engaging portion when moving between the second release positions.
(3) The rotating body is a pinion,
Each of the first connection part and the second connection part has a rack shape,
The first rotation connection portion has a tooth row shape meshing with the first connection portion, and the second rotation connection portion has a tooth row shape meshing with the second connection portion.
(4) The sliding direction of the first movable side engaging portion and the sliding direction of the second movable side engaging portion are parallel.
(5) The input unit is provided in the grabrid,
The length of the first movable side engaging portion in the longitudinal direction is longer than the length of the second movable side engaging portion in the longitudinal direction.

  In the grab box of the present invention, the sliding amount of the first movable side engaging portion is made larger than the sliding amount of the second movable side engaging portion, so that the locking performance of the grabrid by the lock mechanism can be improved. That is, even when the distance between the first movable side engaging portion and the first fixed side engaging portion becomes larger than the target value due to variations in dimensional accuracy, the first movable side engaging portion is slid greatly. Thus, the first movable side engaging portion and the first fixed side engaging portion can be engaged with high reliability.

It is a perspective view showing typically signs that the glove box of Example 1 is carried in vehicles. It is explanatory drawing which represents the grab box of Example 1 typically. It is explanatory drawing which represents the grab box of Example 1 typically. FIG. 3 is an enlarged explanatory view of a main part schematically showing a grab box of Example 1. It is a principal part expansion explanatory drawing which represents typically the grab box of Example 2. FIG. It is a principal part expansion explanatory drawing which represents typically the grab box of Example 3. FIG. It is a principal part expansion explanatory drawing which represents typically the grab box of Example 3. FIG. It is a disassembled perspective view which represents typically the input part in the grab box of Example 3. FIG. It is a principal part expansion explanatory drawing which represents typically the grab box of Example 4. FIG. It is a principal part expansion explanatory drawing which represents typically the grab box of Example 4. FIG. FIG. 10 is an enlarged explanatory view of main parts schematically showing a grab box of Example 5. FIG. 10 is an enlarged explanatory view of main parts schematically showing a grab box of Example 5.

  Hereinafter, the grab box of the present invention will be specifically described.

Example 1
FIG. 1 is a perspective view schematically showing a state in which the grab box of Example 1 is mounted on a vehicle. Further, an explanatory diagram schematically showing the grab box of Example 1 is shown in FIG. 2, and an enlarged explanatory diagram of a main part schematically showing the grab box of Example 1 is shown in FIGS. 3 and 4. Specifically, FIG. 2 shows a grab box in which the first movable side engaging portion is in the first locked position and the second movable side engaging portion is in the second locked position. FIG. 3 is an enlarged view of a main part of FIG. FIG. 4 shows a grab box with the grabbed in the closed position, the first movable side engaging portion in the first release position, and the second movable side engaging portion in the second release position. Hereinafter, in Example 1, “up”, “down”, “front”, and “rear” refer to the upper, lower, front, and rear shown in FIG. The front corresponds to the front side in the vehicle traveling direction. The rear corresponds to the rear side in the vehicle traveling direction, that is, the vehicle interior side.

  As shown in FIGS. 1 and 2, the grab box of the first embodiment includes a case portion 1, a grabrid 2, and a lock mechanism 3. The locking mechanism 3 is not visible from the rear side of the grab box (that is, the vehicle interior side), but is provided inside the grabrid 2 as shown in FIG. The lock mechanism 3 includes a first fixed side engaging portion 40, a second fixed side engaging portion 45, a first movable side engaging portion 50, a second movable side engaging portion 55, an input portion 60, A conversion unit 65.

  The case part 1 is assembled | attached to the instrument panel 90 of a vehicle. Specifically, the case portion 1 has a box shape having an opening 11, and the opening 11 faces the design surface of the instrument panel 90 (that is, the rear surface, the surface exposed to the vehicle interior). In the first embodiment, the case portion 1 is a separate body from the instrument panel 90 and is assembled to the instrument panel 90. However, the case part 1 should just form a box shape as a whole, for example, you may comprise at least one part of the case part 1 with vehicle structural members, such as the instrument panel 90. FIG.

  The grabrid 2 has a shape capable of opening and closing the opening 11 of the case portion 1. For example, the grabrid 2 may have a box shape that can accommodate articles therein, or may simply have a plate shape to open and close the opening 11. In the case where the gloved 2 has a box shape, the case unit 1 may be able to accommodate the gloved 2 inside. The grab lid 2 can change the position between a closed position (FIG. 1) for closing the opening 11 and an open position (not shown) for opening the opening 11. Specifically, the grab lid 2 in the grab box of the first embodiment is guided by a guide mechanism (not shown) and rotates between an open position and a closed position.

  In the grab box of the first embodiment, the input unit 60 of the lock mechanism 3 is provided in the grab lid 2. The input unit 60 has a knob shape. An opening 21 is provided in an area on the driver's seat side in the grab lid 2, and the input unit 60 is disposed inside the opening 21. The input unit 60 can swing with respect to the grabrid 2. The input unit 60 operates when the user pulls the input unit 60 toward the front side (that is, the rear side or the vehicle interior side) or pushes the input unit 60 toward the back side (that is, the front side or the vehicle interior side). A front portion of the input unit 60 is exposed on the front side of the grab lid 2 (that is, the back side, the inside of the case unit 1). An unillustrated tooth row is provided on the front portion of the input unit 60.

  As shown in FIGS. 2 to 4, the first fixed side engaging portion 40 and the second fixed side engaging portion 45 are provided on the side portion of the case portion 1. Specifically, the first fixed side engaging portion 40 and the second fixed side engaging portion 45 each have a frame shape having engaging holes (41, 46) penetrating in the left-right direction. The first fixed side engaging part 40 is provided on the left side wall (not shown) of the case part 1, and the second fixed side engaging part 45 is provided on the right side wall (not shown) of the case part 1. In the grab box of the first embodiment, the first fixed side engaging portion 40 and the second fixed side engaging portion 45 are provided in the case portion 1. Further, as will be described later, the first movable side engaging portion 50 and the second movable side engaging portion 55 are provided in the grab lid 2.

  The 1st movable side engaging part 50 and the 2nd movable side engaging part 55 comprise substantially bowl shape, and are each attached to the inside of the glide 2 so that it can slide to the left-right direction. The first movable side engaging portion 50 is longer than the second movable side engaging portion 55 and is disposed on the left side portion of the grab lid 2. The left end portion of the first movable side engaging portion 50 has a substantially claw shape and faces the engaging hole 41 of the first fixed side engaging portion 40. The second movable side engaging portion 55 is disposed on the right side portion of the grabrid 2. The right end portion of the second movable side engaging portion 55 also has a substantially claw shape and faces the engaging hole 46 of the second fixed side engaging portion 45. The first movable side engaging portion 50 is disengaged from the first fixed side engaging portion 40 and the first lock position (FIGS. 2 and 3) that engage with the first fixed side engaging portion 40. And a first release position (FIG. 4). Further, the second movable side engaging portion 55 is engaged with the second fixed side engaging portion 45 and the second lock position (FIGS. 2 and 3) engaging with the second fixed side engaging portion 45. It slides between the second release position (FIG. 4) to be released. In addition, the 1st movable side engaging part 50 and the 2nd movable side engaging part 55 synchronize with the conversion part 65 mentioned later. Furthermore, the 1st movable side engaging part 50 has the 1st rack 51 which meshes with the 1st pinion part 66 mentioned later. The second movable side engaging portion 55 has a second rack 56 that meshes with a second pinion portion 67 described later.

  The conversion unit 65 includes a pinion 68 in which three pinion units (a first pinion unit 66, a second pinion unit 67, and a third pinion unit not shown) are coaxially integrated. The first pinion part 66 has a larger diameter than the second pinion part 67. The third pinion part meshes with the tooth row (not shown) of the input part 60 described above. Therefore, when the input unit 60 swings, the pinion 68 is rotationally driven. In the grab box of the first embodiment, the pinion 68 driven by the input unit 60 rotates clockwise in FIG.

  The first rack 51 has a rack shape that meshes with the first pinion portion 66. The second rack 56 has a rack shape that meshes with the second pinion portion 67.

  Hereinafter, the operation of the locking mechanism 3 in the grab box of the first embodiment will be described.

  As shown in FIG. 1, when the grabrid 2 is disposed at the closed position that closes the opening of the case portion 1, the first movable side engaging portion 50 is connected to the first fixed side engaging portion 40 as shown in FIG. 2. The second movable side engaging portion 55 is engaged with the second fixed side engaging portion 45. Accordingly, at this time, the position of the grabrid 2 and the case portion 1 cannot change relatively. That is, the grabrid 2 is locked in the closed position.

  When the user pulls the input unit 60, the pinion 68 rotates clockwise in FIG. That is, at this time, the first pinion portion 66 and the second pinion portion 67 constituting the pinion 68 rotate in the clockwise direction in FIG. Then, the first rack 51 engaged with the first pinion portion 66 slides in the right direction in FIG. 2, and the first movable side engaging portion 50 integrated with the first rack 51 is also moved to the right in FIG. Slide in the direction. On the other hand, the second rack 56 engaged with the second pinion portion 67 slides in the left direction in FIG. 2, and the second movable side engaging portion 55 integrated with the second rack 56 is also shown in FIG. Slide in the middle left direction. Then, the engagement between the first movable side engaging part 50 and the first fixed side engaging part 40 is released, and the second movable side engaging part 55 and the second fixed side engaging part 45 are engaged. Is released, and the lock of the grabrid 2 by the lock mechanism 3 is released. That is, at this time, the position of the grabrid 2 can be changed and the opening 11 of the case portion 1 can be opened.

  By the way, when the input unit 60 is provided in the grabrid 2 as shown in FIG. 1, the input unit 60 may be arranged at a position biased to one side in the longitudinal direction in the grab lid 2 as in the grab box of the first embodiment. . This is because the grab box is generally disposed on the passenger seat side of the vehicle, but if the input unit 60 is provided at the position on the driver seat side in the grab lid 2, the driver can easily operate the input unit 60. In this case, according to the position of the input part 60 and the 1st fixed side engaging part 40, and the position of the input part 60 and the 2nd fixed side engaging part 45, the 1st movable side engaging part 50 and the 2nd. It is necessary to set the length of the movable side engaging portion 55 in the longitudinal direction. That is, the length of the first movable side engaging portion 50 in the longitudinal direction needs to be longer than the length of the second movable side engaging portion 55 in the longitudinal direction.

  In the grab box of the first embodiment, the length in the longitudinal direction of the first movable side engaging portion 50 is larger than the length in the longitudinal direction of the second movable side engaging portion 55. Further, the distance from the input unit 60 to the first fixed side engaging unit 40 is larger than the distance from the input unit 60 to the second fixed side engaging unit 45. Furthermore, the distance from the conversion unit 65 to the first fixed side engaging unit 40 is larger than the distance from the input unit 60 to the second fixed side engaging unit 45. For this reason, the relative position between the first movable side engaging portion 50 and the first fixed side engaging portion 40 is compared with the relative position between the second movable side engaging portion 55 and the second fixed side engaging portion 45. It is thought that it becomes easy to shift. In the grab box of Example 1, most of the material is occupied by resin. Since a large resin member is difficult to mold with high dimensional accuracy, the first movable side engaging portion 50, which is a relatively large member, is also difficult to mold with high dimensional accuracy. Further, the case portion 1 which is a relatively large member is also difficult to be molded with high dimensional accuracy. For this reason, the relative position of the 1st movable side engaging part 50 and the 1st fixed side engaging part 40 provided in the case part 1 is comparatively easy to shift | deviate.

  Therefore, the distance between the first movable side engaging part 50 and the first fixed side engaging part 40 may be larger than a predetermined distance. In this case, the stroke of the first movable side engaging part 50 (Sliding amount) may not be sufficient for the first movable side engaging portion 50 and the first fixed side engaging portion 40 to be engaged. That is, even if the second movable side engaging portion 55 and the second fixed side engaging portion 45 are engaged, the first movable side engaging portion 50 and the first fixed side engaging portion 40 may not be engaged. There is sex. In other words, in this type of grab box, there is a possibility that only one of the engaging portions engages and the other engaging portion does not fully engage (so-called lock one-hook phenomenon).

  In order to suppress the above-described one-side lock phenomenon, the first movable-side engagement is provided with a margin for the relative position error between the first movable-side engaging portion 50 and the first fixed-side engaging portion 40. It is considered that the sliding amount of the portion 50 may be made larger than the sliding amount of the second movable side engaging portion 55.

  In the grab box of the first embodiment, the pinion 68 is configured by two pinions 68 having a coaxial and different diameter (a first pinion portion 66 and a second pinion portion 67). The distance from the meshing portion between the first pinion portion 66 and the first rack 51 to the rotation shaft 69 of the pinion 68 is the distance from the meshing portion between the second pinion portion 67 and the second rack 56 to the rotation shaft 69. Bigger than that. Therefore, the movement distance of the first rack 51 when the pinion 68 rotates is larger than the movement distance of the second rack 56, and the sliding amount of the first movable side engaging portion 50 is the second movable side engagement. It becomes larger than the sliding amount of the portion 55. That is, as illustrated in FIG. 4, the conversion unit 65 is configured so that the slide amount L1 of the first movable side engaging unit 50 is larger than the slide amount L2 of the second movable side engaging unit 55. The operation is transmitted to the first movable side engaging portion 50 and the second movable side engaging portion 55. Therefore, according to the grab box of the first embodiment, the locking mechanism 3 can reliably lock the grab lid 2 in the closed position while avoiding or suppressing the above-described one-side lock phenomenon. That is, the grab box of Example 1 is excellent in locking performance.

  In the grab box according to the first embodiment, when the input unit 60 is pushed after the grabrid 2 is placed in the closed position, the pinion 68 rotates counterclockwise in FIG. 2 and the first movable side engaging unit 50 moves to the left. The second movable side engaging portion 55 slides to the right. The first movable side engaging portion 50 is engaged with the first fixed side engaging portion 40, and the second movable side engaging portion 55 is engaged with the second fixed side engaging portion 45. The grab lid 2 is locked again in the closed position. However, for example, in the grab box of the first embodiment, a biasing unit that biases the first movable side engaging portion 50 toward the left and biases the second movable side engaging portion 55 toward the right. It can also be provided. In this case, it is possible to automatically lock the grabrid 2 in the closed position by the lock mechanism 3 simply by placing the grabrid 2 in the closed position.

  The position of the input unit 60 may be set as appropriate in accordance with the layout in the vehicle compartment. Or you may provide in the peripheral part of the grab lid 2 in the instrument panel 90. FIG. Furthermore, although the input unit 60 in the first embodiment is a knob type, for example, a push switch type input unit 60 that is operated by a pressing operation by a user may be applied to the grab box of the present invention.

  Further, the input unit 60 only needs to be able to change its state relative to the grabrid 2. The state change here refers to a state change of at least a part of the input unit 60. That is, if the position of at least a part of the input unit 60 is relatively changed with respect to the grabrid 2 locked in the closed position, the first movable side engaging unit 50 that locks the grablid 2, the first fixed side At least a part of the input unit 60 changes its position relative to at least one of the engaging unit 40, the second movable side engaging unit 55, and the second fixed side engaging unit 45, via the conversion unit 65. Power can be transmitted to at least one of these members.

  In the first embodiment, the first fixed side engaging portion 40 and the second fixed side engaging portion 45 are provided in the case portion 1, and the first movable side engaging portion 50 and the second movable side engaging portion 55 are It is provided in the grabrid 2. However, in the grab box of the present invention, one of the first fixed side engaging portion 40 and the first movable side engaging portion 50 may be provided in the case portion 1 and the other may be provided in the grabrid 2. Then, one of the second fixed side engaging portion 45 and the second movable side engaging portion 55 may be provided in the case portion 1 and the other may be provided in the grab lid 2. That is, even if the first fixed side engaging portion 40 and the second fixed side engaging portion 45 are provided in the grid 2, and the first movable side engaging portion 50 and the second movable side engaging portion 55 are provided in the case portion 1. good. Furthermore, one of the first fixed-side engaging portion 40 and the second fixed-side engaging portion 45 may be provided in the case portion 1 and the other may be provided in the grabrid 2. For example, if the first fixed-side engaging portion 40 is provided in the case portion 1 and the second fixed-side engaging portion 45 is provided in the grabbed 2, the first movable-side engaging portion 50 is provided in the grabbed 2 and the second The movable side engaging portion 55 may be provided on the case portion 1.

  In addition, the grab box may include an opening / closing drive mechanism for automatically or semi-automatically opening and closing the grab lid 2. In this case, it is preferable that at least a part of the operation of the lock mechanism 3 and the operation of the opening / closing drive mechanism be synchronized.

(Example 2)
The grab box of Example 2 is the same as the grab box of Example 1 except that the shape of the pinion is different. FIG. 5 shows an enlarged explanatory view of main parts schematically showing the grab box of Example 2.

  As shown in FIG. 5, the conversion unit 65 in the grab box of the second embodiment is configured by one pinion 68. The pinion 68 includes two tooth rows (a first tooth row 61 and a second tooth row 62). The first tooth row 61 meshes with the first rack 51, and the second tooth row 62 meshes with the second rack 56. The distance between the first tooth row 61 and the rotation shaft 69 is larger than the distance between the second tooth row 62 and the rotation shaft 69. For this reason, also in the grab box of the second embodiment, the moving distance of the first rack 51 when the pinion 68 rotates is larger than the moving distance of the second rack 56, as in the grab box of the first embodiment. . At this time, the sliding amount of the first movable side engaging portion 50 is larger than the sliding amount of the second movable side engaging portion 55. Therefore, the grab box of Example 2 is also excellent in locking performance.

(Example 3)
The grab box of the third embodiment is the same as the grab box of the first embodiment except that the conversion unit is configured by a link mechanism and the structure of the input unit. The principal part expansion explanatory drawing which represents typically the grab box of Example 3 is shown in FIG. 6 and FIG. An exploded perspective view schematically showing the input unit is shown in FIG. FIG. 6 shows a grab box in which the first movable side engaging portion is in the first locked position and the second movable side engaging portion is in the second locked position. FIG. 7 shows a grab box in which the first movable side engaging portion is in the first release position and the second movable side engaging portion is in the second release position.

  As shown in FIG. 6, the conversion unit 65 includes a rotating body 70, two link pins (first rotation connection unit 71, second rotation connection unit 72), and two link holes (first connection unit 73, second connection). Part 74), two guide pins (first guide pin 75, second guide pin 76), and two guide holes (first guide hole 77, second guide hole 78).

  The rotating body 70 is pivotally supported by the grabrid 2 inside the grabrid 2. Two link pins (a first rotation connection portion 71 and a second rotation connection portion 72) are integrally formed on the rotating body 70. The distance between the rotation shaft 69 of the rotating body 70 and the first rotation connection portion 71 is larger than the distance between the rotation shaft 69 and the second rotation connection portion 72. In the grab box of the third embodiment, the first rotation connection portion 71, the rotation shaft 69, and the second rotation connection portion 72 are linearly arranged. In other words, the 1st rotation connection part 71, the rotating shaft 69, and the 2nd rotation connection part 72 are arrange | positioned on the same straight line. Further, the crossing angle between the straight line passing through the first rotation connecting portion 71 and the rotating shaft 69 and the straight line passing through the rotating shaft 69 and the second rotating connecting portion 72 is 180 °.

  A first connecting portion 73 is formed through the first movable side engaging portion 50. A first rotation connection portion 71 is inserted into the first connection portion 73. A second connecting portion 74 is formed through the second movable side engaging portion 55. A second rotation connection portion 72 is inserted into the second connection portion 74.

  The first guide pin 75 and the second guide pin 76 are integrally formed with the rotating body 70. A first guide hole 77 and a second guide hole 78 are recessed in the grab lid 2. The first guide hole 77 and the second guide hole 78 have an arc shape with the rotation shaft 69 as the center. A first guide pin 75 is inserted into the first guide hole 77, and a second guide pin 76 is inserted into the second guide hole 78. The first guide pin 75 can slide in the first guide hole 77, and the second guide pin 76 can slide in the second guide hole 78. The rotating body 70 is stably rotated by being guided by the first guide pin 75, the first guide hole 77, the second guide pin 76, and the second guide hole 78. When the rotating body 70 rotates by a predetermined angle, the first guide pin 75 and the groove end portion of the first guide hole 77 are engaged, and the second guide pin 76 and the groove end portion of the second guide hole 78 are engaged. . For this reason, the first guide pin 75, the first guide hole 77, the second guide pin 76, and the second guide hole 78 also function as a stopper of the rotating body 70.

  Also in the grab box of the third embodiment, the rotating body 70 rotates following the input unit 60. The rotating direction of the rotating body 70 at this time is the clockwise direction in FIG. When the rotating body 70 rotates, the first rotation connecting portion 71 and the second rotation connecting portion 72 formed integrally with the rotating body 70 rotate clockwise on an arc centering on the rotating shaft 69 of the rotating body 70. Moving. The first movable side engaging portion 50 is provided with a first connecting portion 73 that engages with the first rotation connecting portion 71. The second movable side engaging portion 55 is provided with a second connecting portion 74 that engages with the second rotation connecting portion 72. For this reason, the first movable side engaging portion 50 is pulled by the first rotation connecting portion 71 and changes its position, and the second movable side engaging portion 55 is pulled by the second rotating connecting portion 72 and changes its position. Therefore, the 1st movable side engaging part 50 slides substantially linearly in the left-right direction (FIG. 7). Similarly, the second movable side engaging portion 55 also slides substantially linearly in the left-right direction.

  In the grab box of the third embodiment, the distance between the rotation shaft 69 of the rotating body 70 and the first rotation connection portion 71 is larger than the distance between the rotation shaft 69 and the second rotation connection portion 72. For this reason, the movement distance of the 1st rotation connection part 71 accompanying rotation of the rotary body 70 is larger than the movement distance of the 2nd rotation connection part 72, and the 1st movable side engaging part which follows the 1st rotation connection part 71 The slide amount L1 of 50 is larger than the slide amount L2 of the second movable side engaging portion 55 driven by the second rotation connecting portion 72. Therefore, the grab box of Example 3 is also excellent in locking performance.

  By the way, as shown in FIG. 8, the input unit 60 in the grab box of the third embodiment includes a push button 8 and a base unit 9. The push button 8 is disposed on the rear side of the base portion 9 (that is, the vehicle interior side). More specifically, the base portion 9 is provided with a recess 90 corresponding to the outer shape of the push button 8. The recess 90 is depressed toward the front side, and the push button 8 is disposed inside the recess 90. Further, the push button 8 is provided with a first boss portion 81 protruding toward the base portion 9. Furthermore, two standing walls (referred to as input wall portions 85) are provided on the radially outer side of the first boss portion 81. A second boss portion 91 is provided in the recess 90 at a position corresponding to the first boss portion 81. The second boss portion 91 has a cylindrical shape having a larger diameter than the first boss portion 81 (substantially cylindrical shape in the third embodiment), and is further forward from the front surface of the recess 90 (that is, the rotating body 70 side and push button described later). 8 protrudes toward the front side in the pressing direction. The first boss 81 is inserted into the second boss 91. Further, the concave portion 90 is provided with two through holes 92 through which the input wall portion 85 can be inserted at a position corresponding to the input wall portion 85. A corresponding input wall portion 85 is inserted into each through hole 92. Between the push button 8 and the base part 9, the 1st biasing means 89 which consists of a coil spring is interposing. More specifically, the first biasing means 89 is attached to the outside of the first boss portion 81. One end of the first urging means 89 is seated on the front surface of the push button 8, and the other end of the first urging means 89 is seated on the rear surface of the base portion 9 (more specifically, the recess 90). The first urging means 89 urges the push button 8 in the backward direction, that is, in the direction away from the base portion 9.

  The push button 8 is further provided with a key cylinder 82. The key cylinder 82 has a slot (not shown) for inserting a key (not shown). In the concave portion 90 of the base portion 9, a key cylinder base 93 having a shape corresponding to the outer shape of the key cylinder 82 is recessed at a position corresponding to the key cylinder 82. The key cylinder 82 is disposed inside the key cylinder base 93. The key cylinder 82 is provided with a key lock first engaging portion 83 that protrudes toward the key cylinder base 93. To the key cylinder base 93. A through-hole-shaped key lock second engaging portion 94 is provided. When a key (not shown) is inserted into the key cylinder 82 and rotated, the key cylinder 82 is driven by the key, and a lock release position shown in FIG. 8 and a lock position (not shown) rotated 90 ° from the lock release position, It is possible to rotate between. In the unlocked position, the key lock first engaging portion 83 of the key cylinder 82 faces the key lock second engaging portion 94 of the key cylinder base 93. That is, at this time, since the key lock first engaging portion 83 can be retracted into the key lock second engaging portion 94, when the push button 8 is pressed toward the base portion 9, the push button 8 is moved to the base portion 9. Move in the direction of approach. That is, at this time, the push button 8 can be pressed. When the key cylinder 82 is disposed at the lock position, the key lock first engaging portion 83 faces the bottom surface of the key cylinder base 93. Accordingly, at this time, the key lock first engaging portion 83 cannot be retracted. That is, at this time, when the push button 8 is pressed toward the base portion 9, the key lock first engaging portion 83 comes into contact with the bottom surface of the key cylinder base 93. For this reason, the push button 8 cannot approach the base portion 9. In other words, the push button 8 cannot be pressed at this time. Thus, by inserting and rotating the key into the key cylinder 82, the key cylinder is positioned between the unlock position where the push button 8 can be pressed and the lock position where the push button 8 cannot be pressed. 82 can change state.

  Three positioning ribs 95 are provided on the peripheral edge of the second boss portion 91. In addition, three first retaining engagement portions 96 are provided at the protruding end portion of the second boss portion 91. Each first retaining engagement portion 96 has a substantially strip shape, and protrudes radially outward from the outer peripheral surface of the second boss portion 91. Further, the adjacent first retaining engagement portions 96 adjacent to each other are separated from each other in the circumferential direction of the second boss portion 91. The first retaining engagement portion 96 and the positioning rib 95 are separated from each other in the axial direction of the second boss portion 91 (the front-rear direction in FIG. 8). The rotating body 70 is held between the first retaining engagement portion 96 and the positioning rib 95.

  In the grab box of the third embodiment, the rotating body 70 is provided with a bearing 79 having a through hole shape. A second boss portion 91 is inserted through the bearing 79. Therefore, the second boss portion 91 substantially constitutes the rotating shaft 69 of the rotating body 70. Three second retaining engagement portions 97 are provided on the inner surface of the bearing 79. Each second retaining engagement portion 97 has a substantially strip shape and projects from the inner peripheral surface of the bearing 79 inward in the radial direction. The adjacent second retaining engagement portions 97 are separated from each other in the circumferential direction of the bearing 79. The circumferential distance between adjacent second retaining engagement portions 97 is slightly larger than the circumferential length of the first retaining engagement portion 96. Therefore, the first retaining engagement portion 96 can pass between the adjacent second retaining engagement portions 97 when the rotating body 70 is inserted through the second boss portion 91. If the rotary body 70 is rotated by a predetermined angle after the first retaining engagement portion 96 has passed between the second retaining engagement portions 97, the first retaining engagement portion 96 and the second retaining engagement portion 97 will be described. And the rotating body 70 is held by the second boss portion 91. Note that the second boss portion 91 is a rotating shaft 69 of the rotating body 70, and the rotating body 70 is rotatably held with respect to the second boss portion 91.

  The first rotation connecting portion 71 of the rotating body 70 is inserted through the first connecting portion 73 of the first movable side engaging portion 50. The second rotation connecting portion 72 of the rotating body 70 is inserted into the second connecting portion 74 of the second movable side engaging portion 55. The base portion 9 is provided with a first spring seat portion 87, and the rotating body 70 is provided with a second spring seat portion 88. One end of a second urging means 84 made of a tension spring is attached to the first spring seat portion 87. The other end of the second urging means 84 is attached to the second spring seat portion 88. The second urging means 84 is attached to the first spring seat portion 87 and the second spring seat portion 88 in a state where the urging force is accumulated by extending, and urges the rotating body 70 in the counterclockwise direction in FIG. . Then, the first movable side engaging portion 50 attached to the rotating body 70 is biased toward the first lock position, and the second movable side engaging portion 55 attached to the rotating body 70 is moved to the second position. Energize towards the locked position. Therefore, when the grab lid 2 is disposed at the closed position and the push button 8 is not pressed, the first movable side engaging portion 50 is moved by the urging force of the second urging means 84 to the first fixed side engaging portion. The second movable side engaging portion 55 is engaged with the first fixed side engaging portion 45. That is, at this time, the grabrid 2 is locked in the closed position.

  By the way, the two input wall portions 85 provided on the push button 8 have a tapered wall shape in which the protruding height gradually changes. Specifically, the two input wall portions 85 are disposed on the radially outer side of the first cylindrical boss portion 81 and are separated from each other. The protruding direction of each input wall 85 substantially matches the protruding direction of the first boss 81 (that is, the axial direction of the first boss 81). Each input wall portion 85 is slightly curved along the circumferential direction of a circle centered on the first boss portion 81. Further, the protruding height of each input wall portion 85 gradually increases from the front side in the clockwise direction around the first boss portion 81 toward the rear side. On the other hand, the rotating body 70 is provided with two contact surfaces 98 that can abut against the protruding end surfaces 86 of the input wall portions 85. A part of each input wall portion 85 on the protruding end side is inserted into the through hole 92 even when the push button 8 is not pressed. In each input wall portion 85, a portion with a high protruding height (a rear portion in the clockwise direction) is exposed to the front side of the base portion 9 through the through hole 92 and abuts against the contact surface 98 of the rotating body 70. ing. When the user presses the push button 8, the push button 8 and the base portion 9 come close to each other. Then, a portion of the protruding end face 86 of the input wall portion 85 having a relatively small protruding height, that is, a portion positioned on the front side in the clockwise direction is gradually exposed to the front side of the base portion 9 through the through hole 92. To do. For this reason, the contact surface 98 of the rotating body 70 is pressed from the rear side to the front side in the clockwise direction by the protruding end surface 86 of the input wall portion 85. In other words, at this time, the rotating body 70 is pressed and rotated clockwise. Then, the first movable side engaging portion 50 attached to the rotating body 70 slides toward the first release position, and the second movable side engaging portion 55 attached to the rotating body 70 is moved to the second release position. Slide towards. For this reason, the lock of the grabrid 2 is released.

  The input unit 60 in the grab box of the third embodiment has a simple structure and can easily rotate the rotating body 70.

  Note that the input wall 85 in the grab box of the third embodiment has a curved shape along the rotation direction of the rotating body 70, but the shape of the input wall 85 is a tapered wall shape that can rotationally drive the rotating body 70. However, the present invention is not limited to this. For example, the input wall portion 85 may have a flat plate shape whose projecting height gradually changes.

Example 4
The grab box of the fourth embodiment is substantially the same as the grab box of the first embodiment except that the conversion unit is configured by a link mechanism. Further, the grab box of the fourth embodiment is different from the grab box of the third embodiment in that the distance between the first rotation connection portion and the rotation shaft is the same as the distance between the second rotation connection portion and the rotation shaft. FIG. 9 and FIG. 10 show enlarged views of main parts schematically showing the grab box of Example 4. FIG. 9 shows a grab box in which the first movable side engaging portion is in the first locked position and the second movable side engaging portion is in the second locked position. FIG. 10 shows a grab box in which the first movable side engaging portion is in the first release position and the second movable side engaging portion is in the second release position.

  As illustrated in FIG. 9, the conversion unit 65 includes a rotating body 70, two link pins (first rotation connection unit 71, second rotation connection unit 72), and two link holes (first connection unit 73, second connection). Part 74), one guide pin (first guide pin 75), and one guide hole (first guide hole 77).

  The rotating body 70 is pivotally supported by the grabrid 2 inside the grabrid 2 as in the grab box of the third embodiment. Two link pins (a first rotation connection portion 71 and a second rotation connection portion 72) are integrally formed on the rotating body 70. The distance between the rotation shaft 69 of the rotating body 70 and the first rotation connection portion 71 is substantially the same as the distance between the rotation shaft 69 and the second rotation connection portion 72. In the grab box of the fourth embodiment, the first rotation connection portion 71, the rotation shaft 69, and the second rotation connection portion 72 are not linearly arranged. Specifically, in the grab box of the fourth embodiment, a crossing angle (subordinate angle) between a straight line passing through the first rotation connecting portion 71 and the rotating shaft 69 and a straight line passing through the rotating shaft 69 and the second rotating connecting portion 72. ) Is about 140 °.

  A first connecting portion 73 is formed through the first movable side engaging portion 50. The 1st connection part 73 makes a through-hole shape. A first rotation connection portion 71 is inserted into the first connection portion 73. A second connecting portion 74 is formed through the second movable side engaging portion 55. A second rotation connection portion 72 is inserted into the second connection portion 74. In addition, the 1st rotation connection part 71 may be made into a through-hole shape, and the 1st connection part 73 may be made into a pin shape. Similarly, the 2nd rotation connection part 72 may be made into a through-hole shape, and the 2nd connection part 74 may be made into a pin shape.

  The first movable side engaging portion 50 slides between a first lock position shown in FIG. 9 and a first release position shown in FIG. Further, the second movable side engaging portion 55 slides between a second lock position shown in FIG. 9 and a second release position shown in FIG. The sliding direction of the first movable side engaging portion 50 and the sliding direction of the second movable side engaging portion 55 are the left and right directions as in the grab box of the first to third embodiments.

  The first guide pin 75 is integrally formed with the grab lid 2, and the first guide hole 77 is recessed in the rotating body 70. The first guide hole 77 has an arc shape centered on the rotation shaft 69. A first guide pin 75 is inserted into the first guide hole 77. The first guide pin 75 can slide in the first guide hole 77.

  In the grab box of the fourth embodiment, the rotating body 70 rotates counterclockwise in FIG. 10 following the input unit 60. Then, the first rotation connecting portion 71 and the second rotation connecting portion 72 formed integrally with the rotating body 70 move in a counterclockwise direction on an arc centering on the rotating shaft 69 of the rotating body 70. In the fourth embodiment, the radial distance between the rotation shaft 69 and the first rotation connection portion 71 and the radial distance between the rotation shaft 69 and the second rotation connection portion 72 are equal. Therefore, the movement distance of the first rotation connection portion 71 and the movement distance of the second rotation connection portion 72 in the circumferential direction of the rotator 70 (that is, the arc direction around the rotation shaft 69) are equal. However, as shown in FIG. 10, the movement distance of the first rotation connection portion 71 and the second rotation connection portion 72 at this time is determined by the sliding direction of the first movable side engagement portion 50 and the second movable side engagement portion 55. When projected in a straight line direction (that is, in the left-right direction), the movement distance L01 of the first rotation connection portion 71 greatly exceeds the movement distance L02 of the second rotation connection portion 72. Therefore, also in the grab box of the fourth embodiment, the slide amount L1 of the first movable side engaging portion 50 is larger than the slide amount L2 of the second movable side engaging portion 55, and the grab box of the fourth embodiment also has a locking performance. Excellent.

  In the grab box of the fourth embodiment, the first movable side engaging portion 50 slides as a whole while swinging around the first rotation connecting portion 71. Similarly, the second movable side engaging portion 55 slides as a whole while swinging around the second rotation connecting portion 72. However, for example, if the shapes of the first connection portion 73 and the second connection portion 74 are changed as appropriate, the first movable side engagement portion 50 and the second movable side engagement portion 55 may be slid to not swing. it can. For example, if the first connecting portion 73 is formed in a long hole shape orthogonal to the sliding direction of the first movable side engaging portion 50, the first rotation connecting portion 71 slides inside the first connecting portion 73. If it does in this way, the 1st movable side engaging part 50 will only slide, but does not rock | fluctuate. Similarly, in order to avoid the swing of the second movable side engaging portion 55, the second connecting portion 74 is formed in a long hole shape orthogonal to the sliding direction of the second movable side engaging portion 55, and the second rotation. What is necessary is just to make it the connection part 72 slide in the inside of the 2nd connection part 74. FIG.

  By the way, in the direction orthogonal to the sliding direction of the first movable side engaging portion 50 and the second movable side engaging portion 55 (the vertical direction in FIG. 9), the movement amount of the first rotation connecting portion 71 is the second rotation. The amount of movement of the connecting portion 72 is small. That is, the swing amount of the first movable side engaging portion 50 is relatively smaller than the swing amount of the second movable side engaging portion 55. In other words, in the grab box of the fourth embodiment, the swing amounts of the two movable side engaging portions (the first movable side engaging portion 50 and the second movable side engaging portion 55) are different. In the grab box according to the fourth embodiment, the distance between the first movable side engaging portion 50 and the first fixed side engaging portion 40 provided in the case portion 1 is relatively large. The relative position between the engaging portion 50 and the first fixed side engaging portion 40 is relatively easy to shift. In the grab box of the fourth embodiment, the movable side engagement portion is reduced by reducing the swing amount of the movable side engagement portion (the first movable side engagement portion 50 in the fourth embodiment) on the side that is easily displaced. It is possible to increase the arrangement accuracy of the joint portion and the fixed side engaging portion, and to prevent the lock from being hooked.

  Further, in the grab box of the fourth embodiment, the swing amount of the second movable side engaging portion 55 is relatively large. However, as shown in FIG. 9, a guide part 99 for guiding the second movable side engaging part 55 is provided in the grab box, and the second movable side engaging part 55 is provided on the guide part 99 as the second fixed side engaging part. By providing the inclined surface 99a that is guided toward 45, the arrangement accuracy of the second movable side engaging portion 55 and the second fixed side engaging portion 45 is improved, and the second movable side engaging portion 55 and the second The fixed-side engagement portion 45 can be engaged with high reliability.

(Example 5)
The grab box of Example 5 is substantially the same as the grab box of Example 3 except for the shape of the rotating body and the input unit. FIG. 11 and FIG. 12 show enlarged views of main parts schematically showing the grab box of Example 5. FIG. 11 shows a grab box in which the first movable side engaging portion is in the first locked position and the second movable side engaging portion is in the second locked position. FIG. 12 shows a grab box in which the first movable side engaging portion is in the first release position and the second movable side engaging portion is in the second release position.

  In the grab box of the fifth embodiment, the rotating body 70 is provided with a stopper portion 70a. The stopper portion 70 a has a shape that protrudes in the radial direction of the rotating body 70. The protruding end portion of the stopper portion 70 a is located on the outermost side in the radial direction of the rotating body 70. The stopper portion 70a rotates integrally with the rotating body 70.

  Similar to the input unit 60 in the grab box of the third embodiment, the input unit 60 includes a push button 8 and a base unit 9. An opening (not shown) is formed in the base portion 9 instead of the key cylinder base 93. The unillustrated opening is at a position corresponding to the key cylinder 82 of the push button 8.

  The push button 8 includes a key cylinder 82. When a key (not shown) is inserted into the key cylinder 82 and rotated, the key cylinder 82 is driven by the key and can rotate between the locked position shown in FIG. 11 and the unlocked position shown in FIG. The key cylinder 82 is provided with a key lock first engaging portion 83 that protrudes toward the front side. The key lock first engaging portion 83 rotates integrally with the key cylinder 82. The key lock first engaging portion 83 is exposed to the front side of the base portion 9 through an opening (not shown) provided in the base portion 9.

  The distance between the key lock first engaging portion 83 when the key cylinder 82 is in the locked position and the rotation shaft 69 of the rotating body 70 is the same as the key lock first engaging portion 83 when the key cylinder 82 is in the unlocked position. And the distance between the rotary shaft 69 is small. Therefore, as shown in FIG. 11, in the locked position, the key lock first engaging portion 83 of the key cylinder 82 is engaged with the stopper portion 70 a of the rotating body 70, thereby preventing the rotating body 70 from rotating. That is, at this time, even if the user presses the push button 8, the rotating body 70 does not rotate, and the first movable side engaging portion 55 and the second movable side engaging portion 50 cannot slide, and the lock mechanism 3 The lock of grabbed 2 is maintained. The grab box of the fifth embodiment locks the rotary body 70 by directly engaging the key cylinder 82 and the rotary body 70, and thus maintains the lock of the grabrid 2 by the lock mechanism 3. And different. However, also in the grab box of the fifth embodiment, the locked state of the grab lid 2 can be maintained and released using the key (not shown) and the key cylinder 82.

  On the other hand, in the unlocked position, the key lock first engaging portion 83 of the key cylinder 82 does not contact the stopper portion 70 a of the rotating body 70. Therefore, at this time, the rotating body 70 is rotatable, and when the user presses the push button 8, the lock of the grabrid 2 by the lock mechanism 3 is released.

  In addition, the input part 60, the conversion part 65, the 1st movable side engaging part 55, the 1st fixed side engaging part 40, the 2nd movable side engaging part 50, and the 2nd fixed side engagement in the grab box of Example 5 The part 45 has substantially the same shape as each of these members in the grab box of Example 3, and performs substantially the same operation. For this reason, also in the grab box of Example 5, the one-sided phenomenon of the lock is suppressed.

  The grab box of the present invention can be preferably used as a grab box for various vehicles.

1: Case part 2: Grabbed 3: Lock mechanism 40: First fixed side engaging part 45: Second fixed side engaging part 50: First movable side engaging part 55: Second movable side engaging part 60: Input Unit 65: Conversion unit 68: Pinion 69: Rotating shaft 70: Rotating body 71: First rotation connection unit 72: Second rotation connection unit 73: First connection unit 74: Second connection unit

Claims (6)

A box-like case with an opening,
A glide that is displaceable relative to the case portion and can be placed in a closed position to close the opening;
A locking mechanism for locking the grabrid in the closed position,
The locking mechanism is
A first fixed-side engaging portion provided on one of the case portion and the grabrid; and a first movable-side engaging portion provided on the other of the case portion and the grabrid. A first engaging portion,
A second fixed-side engaging portion provided on one of the case portion and the grabrid; and a second movable-side engaging portion provided on the other of the case portion and the grabrid. A second engaging portion,
An input unit capable of changing a state relative to the grabrid;
A conversion unit that connects the input unit, the first movable side engagement unit, and the second movable side engagement unit;
The first movable side engaging portion includes a first lock position that engages with the first fixed side engaging portion, and a first release position that releases the engagement with the first fixed side engaging portion. Can slide between
The second movable side engaging portion includes a second lock position that engages with the second fixed side engaging portion, and a second release position that releases the engagement with the second fixed side engaging portion. Can slide between
In the converting portion, the sliding amount of the first movable side engaging portion between the first lock position and the first release position is such that the slide amount between the second lock position and the second release position is the same. 2 A grab box for transmitting the operation of the input unit to the first movable side engaging portion and the second movable side engaging portion so as to be larger than the sliding amount of the movable side engaging portion. The conversion unit includes a rotating body,
The first movable side engagement portion includes a first connection portion connected to the conversion portion,
The second movable side engaging portion includes a second connecting portion connected to the converting portion,
The rotating body is directly or indirectly connected to a rotating shaft, a first rotation connecting portion that is directly or indirectly connected to the first movable side engaging portion, and the second movable side engaging portion. A first rotation connecting portion,
The grab box according to claim 1, wherein a distance between the rotation shaft of the rotating body and the first connection portion is longer than a distance between the rotation shaft and the second connection portion. The conversion unit includes a rotating body,
The rotating body includes a rotation shaft, a first rotation connection portion positioned on the radially outer side of the rotation shaft, and a second rotation connection spaced apart from the first rotation connection portion and positioned on the radially outer side of the rotation shaft. Have a department
The first movable side engagement portion includes a first connection portion connected to the first rotation connection portion,
The second movable side engagement portion includes a second connection portion connected to the second rotation connection portion,
The distance between the rotation shaft of the rotating body and the first rotation connection portion and the distance between the rotation shaft and the second rotation connection portion are the same,
When moving between the first lock position and the first release position, the linear movement distance of the first rotation connecting portion in the sliding direction of the first movable side engaging portion is the second lock position. 2. The grab box according to claim 1, wherein the grab box is larger than a linear movement distance of the second rotation connecting portion in a sliding direction of the second movable side engaging portion when moving between the second release positions. The rotating body is a pinion;
Each of the first connection part and the second connection part has a rack shape,
3. The grab box according to claim 2, wherein the first rotation connection portion has a tooth row shape meshing with the first connection portion, and the second rotation connection portion has a tooth row shape meshing with the second connection portion.   The grab box according to any one of claims 1 to 4, wherein a sliding direction of the first movable side engaging portion and a sliding direction of the second movable side engaging portion are parallel to each other. The input unit is provided in the grabrid,
The grab box according to any one of claims 1 to 5, wherein a length in a longitudinal direction of the first movable side engaging portion is longer than a length in a longitudinal direction of the second movable side engaging portion.

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