JP5894893B2 - Containment structure device - Google Patents

Description

  The present invention relates to a housing structure device such as a vehicle glove box device.

Conventional housing structure devices are disclosed in, for example, Patent Documents 1, 2, and 3.
(A) In Patent Documents 1 and 2, when the rotating member is moved from the open position to the closed position, the rotating member is manually operated over the entire region from the open position to the closed position until reaching the closed position where the lock is applied. Is disclosed.
(B) Patent Document 3 discloses an apparatus for opening and closing a rotating member using a motor.

However, the conventional housing structure apparatus has the following problems.
(A) Patent Documents 1 and 2
When the rotating member is moved from the open position to the closed position, the rotating member must be manually operated over the entire region from the open position to the closed position, so there is room for improvement in the closing operability of the rotating member.
(B) Patent Document 3
Since a motor is used, a motor and other wiring are necessary, which is disadvantageous in terms of cost.

JP 2007-285021 A JP-A-2005-104192 JP-A-2-267038

  An object of the present invention is to provide a housing structure device that can improve the closing operability of a rotating member as compared with the conventional (A) and is advantageous in cost compared with the conventional (B).

The present invention for achieving the above object is as follows.
(1) a fixing member;
The fixing member can be rotated around a rotation axis between a closed position and an open position, and an opening direction moment around the rotation axis from the closed position to the open position side is the closing position. A rotating member acting in the entire region between the position and the open position;
A closing direction moment generating mechanism that causes the closing member to act on the rotating member in a closing direction moment around the rotation axis from the opening position to the closing position in the entire region between the closing position and the opening position; ,
Have
The relationship between the magnitude of the opening direction moment acting on the turning member and the magnitude of the closing direction moment acting on the turning member by the closing direction moment generating mechanism is as follows:
(A) When the rotating member is between the closed position and the predetermined position located between the closed position and the open position, the magnitude of the closing direction moment is equal to the opening direction moment. Larger than the size,
(B) When the rotating member is in the predetermined position, the magnitude of the closing direction moment is equal to the magnitude of the opening direction moment;
(C) when the rotating member is between the predetermined position and the open position, the magnitude of the opening direction moment is greater than the magnitude of the closing direction moment;
Has been in such a way that,
The closing direction moment generation mechanism includes a base, a fulcrum member, a spring member, and an arm,
The base is fixed to one of the fixing member and the rotating member,
The fulcrum member is fixed to the other of the fixing member and the rotating member,
The arm is applied with a spring force of the spring member at one end in the longitudinal direction, and is supported by the fulcrum member at an intermediate portion in the longitudinal direction. A load that generates a directional moment is applied to the base.
Containment structure device.
( 2 ) The position of the arm supported by the fulcrum member is the other end in the longitudinal direction of the arm as the rotating member moves from the closed position to the open position with respect to the fixed member. The housing structure device according to ( 1 ), which moves from the side to the one end side in the longitudinal direction.

According to the housing structure device of the above (1), the following effects can be obtained.
The relationship between the magnitude of the opening direction moment acting on the pivoting member and the magnitude of the closing direction moment acting on the pivoting member by the closing direction moment generating mechanism is as follows: (a) , The magnitude of the closing direction moment is greater than the magnitude of the opening direction moment, and (b) when the rotating member is in a predetermined position, the magnitude of the closing direction moment is equal to the magnitude of the opening direction moment, c) When the rotating member is between the predetermined position and the open position, the magnitude of the opening direction moment is larger than the magnitude of the closing direction moment. The rotating member can be moved to the closed position only by manually moving to the closed position to a position exceeding the predetermined position. Therefore, the closing operability of the rotating member can be improved as compared with the conventional case (A).

According to the housing structure device of (1), the following effects can be further obtained.
Since the closing moment generated by the closing moment generation mechanism acts on the rotating member in the entire region between the closed position and the open position, it rotates only in a part of the region between the closed position and the open position. Compared with the case of acting on the member, it is possible to suppress a sudden change in the operation load during the opening / closing operation of the rotating member.

According to the housing structure device of ( 1 ) above, the following effects can be obtained.
Since the closing moment generating mechanism includes a spring member that applies a spring force to the arm, a motor for rotating the rotating member in the open position to the closed position side is unnecessary. Therefore, a motor and other wirings are unnecessary, which is advantageous in terms of cost compared to the conventional (B).

According to the housing structure device of ( 1 ), the following effects can be further obtained.
Since the closing direction moment mechanism utilizes the lever principle, the closing direction moment can be applied to the rotating member with a relatively simple structure.

According to the housing structure device of ( 2 ), the following effects can be obtained.
Since the position of the arm supported by the fulcrum member moves from the other end in the longitudinal direction of the arm to the one end in the longitudinal direction as the rotating member moves from the closed position to the open position with respect to the fixed member. The fulcrum in the lever principle moves. Therefore, as the rotating member moves from the closed position to the open position with respect to the fixed member, the load (load at the point of application) applied from the arm to the base using this principle can be gradually reduced. it can. Therefore, as the rotating member moves from the closed position to the open position side with respect to the fixed member, the magnitude of the closing direction moment acting on the rotating member can be gradually reduced by the closing direction moment generating mechanism.

It is a disassembled perspective view of the rotation member and the closing direction moment generation mechanism of the housing structure device of the embodiment of the present invention. It is a side view when the rotation member exists in a closed position of the storage structure apparatus of the present invention embodiment. It is a side view when a rotation member exists in a predetermined position of the accommodation structure device of the example of the present invention. It is a side view when the rotation member exists in an open position of the accommodation structure apparatus of the present invention example. It is a schematic diagram of the lever mechanism part when the rotating member is in the closed position of the housing structure device of the embodiment of the present invention. It is a schematic diagram of the lever mechanism when the rotating member is in a predetermined position of the housing structure device of the embodiment of the present invention. It is a schematic diagram of the lever mechanism part when the rotating member is in the open position of the housing structure device of the embodiment of the present invention. It is a figure which shows the modification of the accommodation structure apparatus of this invention Example, and is a side view when a rotation member exists in a closed position.

Hereinafter, a housing structure apparatus according to an embodiment of the present invention will be described with reference to the drawings. In the figure, FR indicates the front of the vehicle, and UP indicates the upper side.
The housing structure device 10 according to the embodiment of the present invention is, for example, as shown in FIG. It is a glove box device for vehicles. However, the housing structure device 10 may be a so-called door type (a type in which only a door is opened and closed) for a vehicle glove box device. In addition, the housing structure device 10 is not limited to the vehicle glove box device, but may be a vehicle center lower box device disposed at the center and the lower portion of the instrument panel in the vehicle width direction. It may be a vehicle accessory device arranged on the ceiling of the room, or may be another device.
Hereinafter, in the embodiment of the present invention and the illustrated example, the case where the housing structure device 10 is a so-called bin-type vehicle glove box device will be described as an example.

  The housing structure device 10 includes a fixing member 20, a rotating member 30, and a closing direction moment generating mechanism 40.

  The fixing member 20 is a member that is fixed to an instrument panel that is an interior member of the vehicle. The fixing member 20 includes a recess forming wall 21 including a recess 21a that opens to the passenger compartment side (rear side of the vehicle). The recess forming wall 21 may be formed integrally with the instrument panel, or may be formed separately from the instrument panel and fixedly attached to the instrument panel.

As shown in FIG. 1, the rotating member 30 includes an accommodating portion S that opens upward and can accommodate an accommodated item. As shown in FIGS. 2 and 4, the rotation member 30 has a rotation axis P around the fixed member 20 in a vertical direction at a closed position 30 a (see FIG. 2) and an open position 30 b (see FIG. 4). Can be rotated. The pivot axis P extends in the vehicle left-right direction at the lower end portion (including the vicinity thereof) of the pivot member 30.
When the rotating member 30 is in the closed position 30a, the rotating member 30 is locked by a known locking device, and the rotating member 30 in the closed position 30a is against the fixing member 20 against the intention of the user. On the other hand, movement to the open position 30b side is restricted. The rotation member 30 can be moved from the closed position 30a to the open position 30b by unlocking the lock device.
The rotation speed of the rotation member 30 with respect to the fixing member 20 may be controlled by providing a damper (not shown).

When the rotating member 30 is in the closed position 30a shown in FIG. 2, a part of the rotating member 30 (including a member fixed to the rotating member 30) is in contact with the fixed member 20, and the fixed member is no more. The movement to the closing side with respect to 20 is restricted. When the rotating member 30 is in the closed position 30a, the contact sound between the rotating member 30 and the fixing member 20 is generated between the fixing member 20 and the rotating member 30 (including members fixed to the rotating member 30). It is suppressed by cushion rubber 51 provided on at least one of them. When the rotating member 30 is in the closed position 30 a, the opening of the storage portion S is located in the recess 21 a, and the user cannot put in and out the stored matter in the storage portion S.
When the rotating member 30 is in the open position 30b shown in FIG. 4, a stopper 52 provided on the rotating member 30 (including a member fixed to the rotating member 30) is in contact with a stopper (not shown) of the fixed member 20. It is in contact with the portion, and further movement to the open side with respect to the fixing member 20 is restricted. When the rotating member 30 is in the open position 30b, the contact sound between the rotating member 30 and the fixing member 20 is generated by the fixing member 20 and the rotating member 30 (including members fixed to the rotating member 30). It may be suppressed by an unillustrated rubber member provided on at least one of the above. When the rotating member 30 is in the open position 30b, the opening of the housing portion S is located in the vehicle interior through the recess 21a, and the user can put in and out the stored material in the housing portion S.

As shown in FIG. 2, the center of gravity G of the rotation member 30 is located on the vehicle rear side (vehicle interior side) with respect to the rotation axis P of the rotation member 30. The gravity center G of the rotating member 30 is subjected to its own weight from the closed position 30a to the open position 30b. Since the center of gravity G of the rotation member 30 is subjected to its own weight from the closed position 30a to the open position 30b, the rotation member 30 is opened around the rotation axis P from the closed position 30a to the open position 30b. A directional moment (rotational moment) M1 acts in the entire region (including both ends) between the closed position 30a and the open position 30b.
The vehicle front-rear direction distance F (F1, F2, F3) between the center of gravity G and the pivot axis P is such that the pivot member 30 is moved from the closed position 30a to the open position 30b as shown in FIGS. As it moves to the side, it gradually increases gradually. For this reason, the opening direction moment M1 around the rotation axis P acting on the rotation member 30 gradually and gradually increases as the rotation member 30 moves from the closed position 30a to the open position 30b.

As shown in FIG. 2, the closing direction moment generating mechanism 40 applies a closing direction moment (rotational moment) M2 around the rotation axis P from the open position 30b to the closed position side 30a. This is a mechanism that operates in the entire region (including both ends) between 30a and the open position 30b.
The closing direction moment generating mechanism 40 is provided on one side of the rotating member 30 in the left-right direction of the vehicle. However, a pair of closing direction moment generating mechanisms 40 may be provided corresponding to both sides of the turning member 30 in the vehicle left-right direction.
As shown in FIG. 1, the closing moment generating mechanism 40 includes a base 41, a fulcrum member 42, a spring member 43, and an arm 44.

  The base 41 is fixed to one of the fixed member 20 and the rotating member 30, and the fulcrum member 42 is fixed to the other of the fixed member 20 and the rotating member 30. In the embodiment of the present invention and the illustrated example, a case where the base 41 is fixed to the rotating member 30 and the fulcrum member 42 is fixed to the fixing member 20 will be described as an example.

The base 41 is made of metal or resin. The base 41 may be formed integrally with the rotating member 30, or may be formed separately from the rotating member 30 and fixedly attached to the rotating member 30 using screws (not shown). Good.
The base 41 includes a base main body 41a, an arm connecting portion 41b, and a spring engaging portion 41c.

The base body 41a has a substantially flat plate shape. The base 41 is fixed to the rotating member 30 by a base body 41a. When the fulcrum member 42 may interfere with the base main body 41a, the base main body 41a may be provided with an escape portion 41e for suppressing interference with the fulcrum member 42.
The arm connecting portion 41b is provided at the vehicle rear side end portion (including the vicinity) of the base body 41a when the rotating member 30 is in the closed position 30a.
One end of the spring member 43 is engaged (hooked) with the spring engaging portion 41c.

The fulcrum member 42 is made of metal or resin. The fulcrum member 42 is provided so as to protrude from the fixing member 20 to the arm 44 side. The fulcrum member 42 has, for example, a cylindrical pin shape. At least the distal end of the fulcrum member 42 enters the groove 44d of the arm 44 and abuts on the upper edge of the groove 44d. The fulcrum member 42 moves in the longitudinal direction of the groove 44d while sliding on the upper edge of the groove 44d in the groove 44d when the rotating member 30 opens and closes with respect to the fixed member 20.

  As shown in FIG. 2, the spring member 43 is provided to apply a spring force (biasing force) to the arm 44 with respect to the base 41. The spring member 43 is made of a coil spring, for example. However, the spring member 43 is not limited to a coil spring as long as it can apply a spring force to the arm 44, and may be a conston spring, a torsion spring, a leaf spring, or the like. The spring member 43 is engaged (hanged) at one end with the spring engaging portion 41c of the base 41, and includes one end in the longitudinal direction of the arm 44 (the vehicle front side end and the vicinity) at the other end. ) Is engaged (hanged) with a spring engaging portion 44f provided on 44a, and urges one end 44a in the longitudinal direction of the arm 44 downward.

  The arm 44 extends in the longitudinal direction of the arm 44. The longitudinal direction of the arm 44 when the rotating member 30 is in the closed position 30a is the vehicle front-rear direction. The arm 44 may be made of metal or resin. Further, the arm 44 may have a one-part configuration or a multi-part configuration. In the illustrated example of the present invention, the arm 44 has a two-part configuration of a first arm 45 made of metal and a second arm 46 made of resin and fixedly attached to the first arm 45. Shows the case.

  The arm 44 is provided with a groove 44d that extends in the longitudinal direction of the arm 44 and into which the fulcrum member 42 is slidably inserted. However, as shown in FIG. 8 showing a modification of the embodiment of the present invention, when the fulcrum member 42 is in sliding contact with the lower edge of the arm 44 extending in the longitudinal direction of the arm 44, a groove 44d is provided. It does not have to be.

As shown in FIG. 2, the arm 44 is always subjected to the spring force Fa of the spring member 43 on one end in the longitudinal direction of the arm 44 (including the vehicle front side end and the vicinity) 44 a.
The arm 44 is supported by (supported on) the fulcrum member 42 at a longitudinal intermediate portion 44 b of the arm 44. The longitudinal intermediate portion 44b of the arm 44 is between the longitudinal one end 44a (the portion where the spring engaging portion 44f is provided) and the longitudinal other end 44c (the portion connected to the arm connecting portion 41b of the base 41). It is a part in.
The arm 44 is rotatably connected to the arm connecting portion 41 b of the base 41 at the other longitudinal end portion (including the vehicle rear side end portion and the vicinity thereof) 44 c of the arm 44. The other end 44c in the longitudinal direction of the arm 44 is positioned behind the rotation axis P, regardless of the opening / closing position of the rotation member 30 with respect to the fixed member 20. For the connection between the other longitudinal end portion 44c of the arm 44 and the arm connecting portion 41b of the base 41, a circular hole is provided in one of the other end portion 44c of the arm 44 in the longitudinal direction and the arm connecting portion 41b of the base 41. This is performed by providing a cylindrical pin inserted into the circular hole on the other of the other end 44c in the longitudinal direction and the arm connecting portion 41b of the base 41. A rotation axis P <b> 1 with respect to the base 41 of the arm 44 is parallel to the rotation axis P of the rotation member 30.

(I) The spring force Fa of the spring member 43 is applied to one end 44 a in the longitudinal direction of the arm 44. (Ii) The arm 44 is supported by the fulcrum member 42 at the longitudinal intermediate portion 44b. (Iii) The arm 44 is rotatably connected to the base 41 at the other end 44c in the longitudinal direction. According to (i) to (iii), on the principle of the lever, the position of the arm 44 to which the spring force Fa of the spring member 43 is applied is the force point, the position of the arm 44 supported by the fulcrum member 42 is the fulcrum, and the arm connecting portion 41b of the base 41 The position of the arm 42 to be connected becomes the point of action, and an upward force Fb acts on the arm connecting portion 41 b of the base 41. The force Fb is a load that causes the rotating member 30 to generate a closing direction moment M2 around the rotation axis P. A closing direction moment (rotational moment) M2 around the rotation axis P acts on the rotation member 30 by the force Fb.

Since the arm 44 is connected to a base 41 fixed to the rotating member 30 at the other end 44c in the longitudinal direction, and the fulcrum member 42 is fixed to the fixing member 20, the rotating member As 30 moves from the closed position 30 a to the open position 30 b relative to the fixed member 20, the fulcrum member 42 moves from the other longitudinal end 44 c side (vehicle rear side) to the longitudinal one end 44 a side (on the vehicle rear side). Move (slide) to the front of the vehicle. That is, the position of the arm 44 supported by the fulcrum member 42 (the position of the fulcrum in the lever principle) is such that the rotating member 30 is in relation to the fixed member 20 as shown in FIG. 5, FIG. 6, and FIG. As it moves from the closed position 30a to the open position 30b, the arm 44 moves from the longitudinal other end 44c to the longitudinal one end 44a. For this reason, the force Fb gradually and gradually decreases as the rotating member 30 moves from the closed position 30a to the open position 30b as shown in FIG. 5, FIG. 6, and FIG. Therefore, the closing direction moment M2 applied to the rotating member 30 by the closing direction moment generating mechanism 40 is such that the rotating member 30 moves from the closed position 30a to the open position 30b side as shown in FIGS. As it moves, it gradually decreases gradually.

The relationship between the magnitude of the opening direction moment M1 acting on the rotating member 30 and the magnitude of the closing direction moment M2 acting on the rotating member 30 by the closing direction moment generating mechanism 40 is as follows.
(A) When the rotating member 30 is between the predetermined position 30c between the closed position 30a and the open position 30b and the closed position 30a, the magnitude of the closing direction moment M2 is the opening direction moment M1. Larger than
(B) When the rotating member 30 is at the predetermined position 30c, the magnitude of the closing direction moment M2 and the magnitude of the opening direction moment M1 are equal (balanced).
(C) When the rotating member 30 is between the predetermined position 30c and the open position 30b, the magnitude of the opening direction moment M1 is larger than the magnitude of the closing direction moment M2.

Next, the operation of the embodiment of the present invention will be described.
The relationship between the magnitude of the opening direction moment M1 acting on the turning member 30 and the magnitude of the closing direction moment M2 acting on the turning member 30 by the closing direction moment generating mechanism 40 is as follows. When the position is between the predetermined position 30c and the closed position 30a, the magnitude of the closing direction moment M2 is larger than the magnitude of the opening direction moment M1, and (b) when the rotating member 30 is at the predetermined position 30c, the closing direction moment M2 Is equal to the magnitude of the opening direction moment M1, and (c) when the rotating member 30 is between the predetermined position 30c and the opening position 30b, the magnitude of the opening direction moment M1 is greater than the magnitude of the closing direction moment M2. Since it is made large, the rotating member 30 at the open position 30b is manually moved to the closed position 30a side to a position exceeding the predetermined position 30c. In, it is possible to move the rotating member 30 is automatically in the closed position 30a side. Therefore, the closing operability of the rotating member can be improved as compared with the conventional case (A).

Since the closing direction moment M2 generated by the closing direction moment generation mechanism 40 acts on the rotating member 30 in the entire region between the closing position 30a and the opening position 30b, the distance between the closing position 30a and the opening position 30b is one. Compared with the case where it acts on the rotating member 30 only in the region of the portion, it is possible to suppress the operation load from changing suddenly when the rotating member 30 is opened and closed.

Since the closing direction moment generating mechanism 40 includes the spring member 43 that applies a spring force to the arm 44, a motor for rotating the rotating member 30 at the open position 30b toward the closed position 30a is not necessary. Therefore, a motor and other wirings are unnecessary, which is advantageous in terms of cost compared to the conventional (B).

Since the closing direction moment mechanism 40 uses the lever principle, the closing direction moment M2 can be applied to the rotating member 30 with a relatively simple structure.

Since the closing direction moment mechanism 40 uses the lever principle, the magnitude of the closing direction moment M2 is smoothed as the rotating member 30 moves from the closing position 30a to the opening position 30b with a relatively simple structure. Can be gradually reduced.

The position of the arm 44 supported by the fulcrum member 42 is longer from the other end 44c in the longitudinal direction of the arm 44 as the rotating member 30 moves from the closed position 30a to the open position 30b with respect to the fixed member 20. Since it moves to the direction one end 44a side, the fulcrum in the lever principle moves. Therefore, as the rotating member 30 moves from the closed position 30a to the open position 30b with respect to the fixed member 20, the distance from the power point to the fulcrum in the lever principle gradually decreases, and the point from the lever in the lever principle to the action point. The distance to gradually increases. Therefore, as the rotating member 30 moves from the closed position 30a to the open position 30b with respect to the fixed member 20, the load applied by using this principle from the arm 44 to the base 41 (load at the point of application) is applied. Can be gradually reduced. Therefore, as the turning member 30 moves from the closed position 30a to the open position 30b with respect to the fixed member 20, the magnitude of the closing direction moment M2 acting on the turning member 30 by the closing direction moment generating mechanism 40 is made smoother. Can be gradually reduced.

The opening direction moment M1 acting on the rotating member 30 gradually and gradually increases as the rotating member 30 moves from the closed position 30a to the open position 30b. Further, the closing direction moment M2 acting on the rotating member 30 by the closing direction moment generating mechanism 40 gradually decreases gradually as the rotating member 30 moves from the closed position 30a to the open position 30b. As described above, since the balance between the opening direction moment M1 and the closing direction moment M2 changes gradually and smoothly, it is possible to prevent a sudden load change from occurring when the rotating member 30 is opened.

DESCRIPTION OF SYMBOLS 10 Housing structure apparatus 20 Fixing member 30 Rotating member 30a Closed position 30b Open position 30c Predetermined position 40 Closing direction moment generation mechanism 41 Base 41a Base main body 41b Arm connection part 41c Spring engaging part 42 Support point member 43 Spring member 44 Arm 44a Arm longitudinal end 44b Arm longitudinal intermediate 44c Arm longitudinal other end M1 Opening moment M2 Closing moment P Rotating pivot axis P1 Rotating pivot core with respect to arm base

Claims (2)

A fixing member;
The fixing member can be rotated around a rotation axis between a closed position and an open position, and an opening direction moment around the rotation axis from the closed position to the open position side is the closing position. A rotating member acting in the entire region between the position and the open position;
A closing direction moment generating mechanism that causes the closing member to act on the rotating member in a closing direction moment around the rotation axis from the opening position to the closing position in the entire region between the closing position and the opening position; ,
Have
The relationship between the magnitude of the opening direction moment acting on the turning member and the magnitude of the closing direction moment acting on the turning member by the closing direction moment generating mechanism is as follows:
(A) When the rotating member is between the closed position and the predetermined position located between the closed position and the open position, the magnitude of the closing direction moment is equal to the opening direction moment. Larger than the size,
(B) When the rotating member is in the predetermined position, the magnitude of the closing direction moment is equal to the magnitude of the opening direction moment;
(C) when the rotating member is between the predetermined position and the open position, the magnitude of the opening direction moment is greater than the magnitude of the closing direction moment;
Has been in such a way that,
The closing direction moment generation mechanism includes a base, a fulcrum member, a spring member, and an arm,
The base is fixed to one of the fixing member and the rotating member,
The fulcrum member is fixed to the other of the fixing member and the rotating member,
The arm is applied with a spring force of the spring member at one end in the longitudinal direction, and is supported by the fulcrum member at an intermediate portion in the longitudinal direction. The arm is closed by utilizing this principle at the other end in the longitudinal direction. A load that generates a directional moment is applied to the base.
Containment structure device. The position of the arm supported by the fulcrum member is determined from the other end in the longitudinal direction of the arm as the rotating member moves from the closed position to the open position with respect to the fixed member. moves in one longitudinal end side, receiving structure according to claim 1, wherein.

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